Expression Of Transcription Factor Encoding Genes

ABSTRACT

Constructs, vectors and methods that facilitate the constitutive expression of transcription factor encoding genes in specific cell types are described.

RELATED APPLICATIONS AND INCORPORATION BY REFERENCE

This application claims benefit of UK patent application Serial No. 1113499.6 filed 5 Aug. 2011.

The foregoing applications, and all documents cited therein or during their prosecution (“appln cited documents”) and all documents cited or referenced in the appln cited documents, and all documents cited or referenced herein (“herein cited documents”), and all documents cited or referenced in herein cited documents, together with any manufacturer's instructions, descriptions, product specifications, and product sheets for any products mentioned herein or in any document incorporated by reference herein, are hereby incorporated herein by reference, and may be employed in the practice of the invention. More specifically, all referenced documents are incorporated by reference to the same extent as if each individual document was specifically and individually indicated to be incorporated by reference.

FIELD OF THE INVENTION

The invention relates to the field of molecular engineering and providing systems and compositions for gene expression in an organism.

INTRODUCTION

Transcription factors control gene expression by interacting with a gene sequence, such as a promoter regulatory sequence. The interaction may be direct sequence-specific binding and the transcription factor directly contacts the gene or gene regulatory sequence. Alternatively, the transcription factor may interact with other proteins to control gene expression. In some cases, the binding and/or effect of one transcription factor is influenced (in an additive, synergistic or inhibitory manner) by another transcription factor.

Manipulation of the expression of transcription factors allows for manipulation of downstream gene expression of target genes of interest as expression of the transcription factor will affect downstream gene expression. Thus, through constitutive gene expression of a transcription factor, downstream gene expression of a gene of interest can also be enhanced.

Promoters that confer constitutive expression in various organisms are known. In plants, the 35S promoter from cauliflower mosaic virus has been widely used. Promoters from other viruses have also been shown to confer similar activity. Whilst constitutive expression of a transgene driven by the 35S promoter is not limited to a specific tissue, it is often desirable to target gene expression to certain sites within an organism and this can be achieved through the use of tissue specific promoters.

The present invention provides alternative means for constitutive expression of a transcription factor in a cell, tissue or organ where it is normally expressed as well as in a cell, tissue or organ where it is not normally expressed.

Citation or identification of any document in this application is not an admission that such document is available as prior art to the present invention.

SUMMARY

The invention relates to constructs, vectors, systems and methods for constitutive expression of a transcription factor gene by creating a positive feedback loop of expression. Thus, it relates to constitutive expression of transcription factor (TF) encoding genes in a cell, tissue or organism using target gene promoter-transcription factor (TART) fusions. In this way, the expression of the downstream target gene may be increased. In one aspect, the invention relates to an expression construct for constitutive expression of a transcription factor gene which may comprise an isolated nucleic acid sequence encoding a transcription factor operably linked to an isolated promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene.

In another aspect, the invention relates to a vector which may comprise an expression construct as described above. Also within the scope of the invention is a host cell expressing such a vector or construct and the use of an expression construct described above for constitutive expression of a transcription factor gene.

In another aspect, the invention relates to a method for constitutive expression of a transcription factor gene which may comprise introducing the expression construct which may comprise an isolated nucleic acid sequence encoding a transcription factor operably linked to an isolated promoter nucleic acid sequence into a host cell or organism wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene.

In a further aspect, the invention relates to a method for constitutive expression of a transcription factor gene which may comprise introducing into a host cell or organism a first expression construct which may comprise an isolated nucleic acid sequence encoding a transcription factor gene operably linked to an isolated promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene and introducing a second expression construct into said host cell or organism wherein said second expression construct may comprise an isolated nucleic acid sequence encoding said transcription factor operably linked to a second isolated promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed.

Thus, in one aspect, the invention relates to methods for differential gene expression. These methods comprise constitutive expression of a gene in a tissue or organ where it is not normally expressed.

The organism according to all of the aspects of the invention is prokaryotic or eukaryotic. In a preferred embodiment, the organism is a plant and the nucleic acid sequences described herein are derived from plants.

Accordingly, it is an object of the invention to not encompass within the invention any previously known product, process of making the product, or method of using the product such that Applicants reserve the right and hereby disclose a disclaimer of any previously known product, process, or method. It is further noted that the invention does not intend to encompass within the scope of the invention any product, process, or making of the product or method of using the product, which does not meet the written description and enablement requirements of the USPTO (35 U.S.C. §112, first paragraph) or the EPO (Article 83 of the EPC), such that Applicants reserve the right and hereby disclose a disclaimer of any previously described product, process of making the product, or method of using the product.

It is noted that in this disclosure and particularly in the claims and/or paragraphs, terms such as “comprises”, “comprised”, “comprising” and the like can have the meaning attributed to it in U.S. Patent law; e.g., they can mean “includes”, “included”, “including”, and the like; and that terms such as “consisting essentially of” and “consists essentially of” have the meaning ascribed to them in U.S. Patent law, e.g., they allow for elements not explicitly recited, but exclude elements that are found in the prior art or that affect a basic or novel characteristic of the invention.

These and other embodiments are disclosed or are obvious from and encompassed by, the following Detailed Description.

BRIEF DESCRIPTION OF THE DRAWINGS

The following detailed description, given by way of example, but not intended to limit the invention solely to the specific embodiments described, may best be understood in conjunction with the accompanying drawings.

FIG. 1. Schematic representation of transcription factor (T) genes, their target (TAR) genes and a TAR-T gene fusion.

FIG. 2. Schematic representation of RSL4 transcription factor gene, its target (EXP7) genes and a EXP7-RSL4 gene fusion.

FIG. 3. A: Schematic gene expression in a non-transformed organism; B: positive transcriptional feed back resulting from fusing a target promoter (TAR) to the transcription factor (T) that regulates its transcriptional activity.

FIG. 4. A: Gene expression in a non-transformed Arabidopsis root hair cell; B: positive transcriptional feed back resulting from fusing a target promoter (EXP7) to the RSL4 gene, which controls transcription from the EXP7 promoter.

FIG. 5. A (left hand side): wild type plants; B (right hand side): Plants transformed with EXP7:RSL4 transgene C: Plants transformed with 35S:RSL4 transgene.

FIG. 6. A (left hand side): wild type plants; B (right hand side): Plants transformed with 35S:RSL4 transgene.

DETAILED DESCRIPTION

The present invention will now be further described. In the following passages, different aspects of the invention are defined in more detail. Each aspect so defined may be combined with any other aspect or aspects unless clearly indicated to the contrary. In particular, any feature indicated as being preferred or advantageous may be combined with any other feature or features indicated as being preferred or advantageous.

The practice of the present invention will employ, unless otherwise indicated, conventional techniques of botany, microbiology, tissue culture, molecular biology, chemistry, biochemistry and recombinant DNA technology, which are within the skill of one in the art. Such techniques are explained fully in the literature.

The present invention relates to a chimeric/heterologous gene or expression construct which may comprise an isolated polynucleotide sequence operably linked to an isolated promoter nucleic acid sequence. The nucleic acid sequence is “heterologous” or “chimeric” with respect to the promoter sequence as this promoter sequence does not function in nature, i.e. in a wild type organism, to regulate the expression of the transcription factor gene.

Transcriptional activation of genes, including transgenes, is in general controlled by a promoter sequence through a complex set of protein/DNA and protein/protein interactions. Promoters are regulatory sequences that may impart patterns of expression that are either constitutive or limited to specific tissues or times during development. As used herein, the term “promoter” refers to a nucleic acid sequence that functions to direct transcription of a gene. A promoter sequence may comprise binding sites for a protein which regulates transcription of the downstream gene.

Thus in a first aspect, the invention relates to an expression construct for constitutive expression of a transcription factor gene which may comprise an isolated nucleic acid sequence encoding a transcription factor operably linked to an isolated promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene. The transcription factor gene thus encodes a protein that interacts with said promoter sequence or interacts with another protein which in turn interacts with the promoter sequence to direct the expression of a downstream target gene. Thus, the transcription factor upregulates its own expression in a positive feedback loop. The promoter and transcription factor nucleic acid sequences are preferably, as described herein, both endogenous to the organism in which the expression construct of the invention is expressed, but in a wild type organism, they are not operably linked.

The transcription factor regulates expression of said target gene from which the promoter is derived. This may be directly or indirectly, for example the transcription factor may bind directly to the promoter or indirectly. In one embodiment, the transcription factor positively regulates expression of said target gene indirectly. For example, the transcription factor binds to the promoter of another gene that encodes a proteins that in turn binds to the promoter.

The downstream target gene is a gene endogenous to the organism and not a further transgene.

As used herein, the term “gene” means the segment of DNA involved in producing a polypeptide chain, which may or may not include regions preceding and/or following the coding region, e.g. 5′ untranslated (5′UTR) or “leader” sequences and 3′UTR or “trailer” sequences, as well as intervening sequences (introns) between individual coding segments (exons). The term “gene” may be used interchangeably herein with the terms “isolated nucleic acid sequence” and “isolated polynucleotide”. The gene has a sequence which encodes a transcription factor and is thus a polynucleotide which may comprise the coding sequence of the transcription factor (i) in isolation, (ii) in combination with additional coding sequences, such as fusion protein or signal peptide, in which the transcription factor coding sequence is the dominant coding sequence, (iii) in combination with non-coding sequences, such as control elements and terminator elements, effective for expression of the coding sequence in a cell.

An increase in gene expression as used herein may be at least 10%, at least 20%, at least 30%, at least 40%, at least 50% or more.

As used herein, the term “operably linked” means that the promoter nucleic acid sequence and transcription factor nucleic acid sequence of the expression construct are in a functional relationship with each other. Thus, the promoter is operably linked to the transcription factor nucleic acid sequence if it affects the transcription of said transcription factor nucleic acid sequence.

As explained in more detail below, the expression construct described herein may, when introduced into a host cell or organism, be used to achieve constitutive expression of a transcription factor gene through a positive feedback loop in a host cell, tissue or organ in which the transcription factor gene is normally expressed. Thus, the nucleic acid encoding a transcription factor gene is preferably a nucleic acid which encodes a transcription factor that is expressed in a specific cell, tissue or organ and/or under specific conditions in a wild type organism.

Furthermore, it is also preferred that the isolated promoter nucleic acid sequence used in the expression construct is a cell, tissue or organ specific promoter and/or regulates gene expression under specific conditions, for example environmental conditions. Thus, in one embodiment, the promoter directs the expression of a downstream target gene of the transcription factor in the same cell, tissue or organ in which the transcription factor gene is normally expressed. Therefore, in a preferred embodiment, the expression construct described herein may be used according to the methods of the invention to drive the expression of the transcription factor gene in those cells, tissues or organs where the transgene product is desired and normally expressed, leaving other cells, tissues or organs unmodified by transgene expression. This is advantageous over the use of expression constructs that use constitutive promoters such as CaMV35S to achieve constitutive expression because using the constructs of the invention, expression may be spatially regulated. Moreover, using developmentally regulated promoters, the timing of gene expression may also be regulated.

As used herein, the term “expression” refers to the process by which a polypeptide is produced based on the nucleic acid sequence of a gene. The process generally includes both transcription and translation.

In one embodiment, the expression construct(s) described herein includes other transcriptional and translational regulatory sequences such as, but not limited to, ribosomal binding sites, transcriptional start and stop sequences, translational start and stop sequences, elements that are responsive to certain environmental conditions, such as heat shock elements, and enhancer, control, terminator or activator sequences. In one embodiment, the vectors and constructs of the invention do not comprise any additional regulatory sequence.

According to the invention, the promoter and transcription factor nucleic acid sequences are both derived from the same type of organism, preferably from the same species. For example, in one embodiment, the promoter and transcription factor nucleic acid sequences are both derived from a prokaryotic organism. In another embodiment, the promoter and transcription factor nucleic acid sequences are both derived from a eukaryotic organism. Examples of a prokaryotic organism are gram-negative bacteria, including E. coli, and gram-positive bacteria. The eukaryotic organism may be yeast, an animal, or a plant. In one embodiment, the eukaryotic organism is an animal, for example a mammal, such as a rodent. In one embodiment, the animal may be a mouse. In a preferred embodiment, the eukaryotic organism is a plant.

As will be immediately apparent to the skilled person, the methods described herein may be used in any type of organism and expression construct for use in an organism of interest and may be designed accordingly. Many transcription factors and their target genes are known in a wide range of organisms and a skilled person would be able to select a transcription factor that targets a gene of interest to manipulate the expression of the target gene and use said sequence to obtain an expression construct according to the invention.

Also within the scope of the invention are artificial promoters that have been specifically designed to not only include sequences to which the specific transcription factor or another protein whose expression is regulated by the transcription factor binds, but also include other sequence features, such as binding sites for inducers etc.

In a preferred embodiment of the different aspects of the invention, the eukaryotic organism is a plant. Thus, in one embodiment, the plant promoter is operably linked to a plant transcription factor gene. A typical plant transcription factor gene may comprise a DNA-binding region, an oligomerization site, a transcription-regulation domain and a nuclear localization signal. Most plant transcription factors exhibit only one type of DNA-binding and oligomerization domain, occasionally in multiple copies, but some contain two distinct types. DNA-binding regions are normally adjacent to or overlap with oligomerization sites, and their combined tertiary structure determines critical aspects of transcription factor activity.

Thus, in this embodiment of the invention, the plant promoter operably linked to a plant transcription factor gene is derived from a downstream target gene of the transcription factor and therefore also a plant sequence, preferably from the same plant species. The promoter used in the constructs of the invention is preferably cell, tissue or organ specific and/or regulates expression during certain developmental stages or under specific conditions, such as biotic or abiotic stress. The transcription factor may direct the expression of the transcription factor in any specific plant tissue or organ, including reproductive and non-reproductive organs. For example, expression may be targeted to in a tissue selected from the following non-limiting list: root, meristem, flower, seed, pollen, embryo, leaf, stem or fruit.

Plant transcription factor classes are known to the person skilled in the field. For example, a non-limiting list of transcription factor families in the model plant Arabidopsis thaliana is shown below (from Riechmann and Ratcliff, 2000). A skilled person would know that TFs in Arabidopsis thaliana have orthologues in other plant species, including monocot crop plants. This is described in the art.

Table 1. Non-Limiting List of Transcription Factor Families in Arabidopsis

-   -   MYB (involved in secondary metabolism, cellular morphogenesis,         signal transduction in plant growth, abiotic and biotic stress         responses, circadian rhythm and dorsoventrality). This family         includes genes such as AtMYB2, ATR1, CCA1, CPC, GL1, LHY, WER.         198 genes in the MYB superfamily from Arabidopsis have been         identified in an analysis of the complete Arabidopsis genome         sequence, among them, 126 are R2R3-MYB, 5 are R1R2R3-MYB, 64 are         MYB-related, and 3 atypical MYB genes (Yanhui et al, Dubos et         al).     -   AP2/EREBP (involved in development, cell proliferation,         secondary metabolism, abiotic and biotic stress responses,         hormone signalling). AP2 (APETALA2) and EREBPs         (ethylene-responsive element binding proteins) are the         prototypic members of a family of transcription factors unique         to plants, whose distinguishing characteristic is that they         contain the so-called AP2 DNA-binding domain. AP2/REBP genes         form a large multigene family, and they play a variety of roles         throughout the plant life cycle: from being key regulators of         several developmental processes, like floral organ identity         determination or control of leaf epidermal cell identity, to         forming part of the mechanisms used by plants to respond to         various types of biotic and environmental stress. AP2/EREBP         genes are divided into two subfamilies: AP2 genes with two AP2         domains and EREBP genes with a single AP2/ERF (Ethylene         Responsive Element Binding Factor) domain. Expressions of         AP2-like genes, including AP2, in Arabidopsis thaliana are         regulated by the microRNA miR172. The target site of miR172 is         significantly conserved in gymnosperm AP2 homologs, suggesting         that regulatory mechanisms of gene expression using microRNA         have been conserved over the three hundred million years since         the divergence of gymnosperm and flowering plant lineages.         Members of this family possess an AP2 domain. In the A. thaliana         transcription factor RAV1 the N-terminal AP2 domain binds a         5′-CAACA-3′ sequence, while the C-terminal highly conserved B3         domain binds a 5′-CACCTG-3′ sequence. There are orthologues in,         for example, Oryza sativa subsp. Indica, Oryza sativa subsp.         Japonica, Sorghum bicolor, Zea mays and Populus trichocarpa.

This family includes genes such as ABI4, ANT, AP2, CBF1-3/DREB1A-C, DREB2A, ERF transcription factors, such as ERF1 (Riechmann et al, 1998).

-   -   NAC (involved in development, pattern formation and organ         separation, stress response). This family includes genes such as         CUC2, NAP, NAC SECONDARY WALL THICKENING PROMOTING FACTOR1         (NST1) and NST3 and, in rice, OsNAC6 (Olsen et al).     -   bHLH/MYC (involved in anthocyanin biosynthesis, light response,         flower development, formation of secondary cell walls and         abiotic stress). There are 133 bHLH genes in Arabidopsis         thaliana and at least 113 of them are expressed. The AtbHLH         genes constitute one of the largest families of transcription         factors in A. thaliana with significantly more members than are         found in most animal species and about an equivalent number to         those invertebrates. Comparisons with animal sequences suggest         that the majority of plant bHLH genes have evolved from the         ancestral group B class of bHLH genes. By studying the AtbHLH         genes collectively, twelve subfamilies have been identified.         Within each of these main groups, there are conserved amino acid         sequence motifs outside the DNA binding domain. Typically, a         bHLH domain may comprise a stretch of about 18 hydrophilic and         basic amino acids at the N-terminal end of the domain, followed         by two regions of hydrophobic residues predicted to form         amphipathic α helices. separated by an intervening loop. This         family includes genes such as PIFs, e.g. PIF3 (Heim et al).     -   bZIP (involved in seed-storage gene expression,         photomorphogenesis, leaf development, flower development defense         response, ABA response, and gibberellin biosynthesis). The         Arabidopsis genome sequence contains 75 distinct members of the         bZIP family, This family includes genes such as ABI5, HY5, PAN.         Members are also known for example in rice (Nijhawan et al) and         soybean. These include root and vascular specific TFs.     -   HB or HD-Zip proteins (involved in leaf, root, internode         development, stem cell identity, cell anthocyanin accumulation,         and cell death differentiation, growth responses). This family         includes genes such as ANL2, ATHB-2, BEL1, GL2, KNAT1, REV, STM,         WUS.

HD-Zip proteins characterized by the presence of a homeodomain associated with a leucine zipper constitute one family of plant transcription factors. The association of the DNA binding domain (HD) with an adjacent dimerization motif (leucine zipper abbreviated ZipLZ or LZ) is a combination found only in the plant kingdom, although the domains are found independently of each other in a large number of eukaryotic transcription factors. This large family of plant TFs has been divided into four subfamilies (I to IV) according to sequence similarity in and outside the conserved domains and by the intron/exon patterns of the corresponding genes. Members of subfamily I interact with the pseudopalindromic sequence CAAT(A/T)ATTG; subfamily II proteins recognize a motif CAAT(C/G)ATTG. In all cases, the formation of protein homo- or hetero-dimers is a prerequisite for DNA binding. Members of the HD-Zip family exhibit a LZ motif just downstream from the HD motif. The two motifs are present in transcription factors belonging to other eukaryotic kingdoms, but their association with each other in a single protein is unique to plants. The HD is responsible for the specific binding to DNA while the LZ acts as a dimerization motif. HD-Zip proteins bind to DNA as dimers, and the absence of the LZ absolutely abolishes their binding ability, indicating that the relative orientation of the monomers, driven by this motif, is crucial for an efficient recognition of DNA.

In Arabidopsis, subfamily I is composed of seventeen members (ATHB1/HAT5, 3/HAT7, 5, 6, 7, 12, 13, 16, 20, 21, 22, 23, 40, 51, 52, 53, 54). HD-Zip I subsets of genes (in Arabidopsis) share their intron/exon distribution in accordance with their phylogenetic relationships. The molecular weight of the encoded proteins is about 35 kDa and exhibit a highly conserved HD and a less conserved LZ. There are numerous homologs and orthologs in other plants.

-   -   Z-C₂H₂ (involved in flower development, flowering time, seed         development, and root

nodule development). This family includes genes such as FIS2, SUP 352 (Englebrecht et al).

-   -   MADS (involved in flower development, fruit development,         flowering time and root development). MADS-box transcription         factors are key regulators of several plant development         processes. Analysis of the complete Arabidopsis genome sequence         revealed 107 genes encoding MADS-box proteins, of which 84% are         of unknown function. These are divided into five groups (named         MIKC, Mα, Mβ, Mγ, Mδ) based on the phylogenetic relationships of         the conserved MADS-box domain.

The MIKC type has a characteristic modular structure. From the N- to the C-terminus of the protein, four characteristic domains may be identified: the MADS-box (M), intervening (I), keratin-like (K), and C-terminal (C) domains. The MADS-box is a DNA binding domain of about 58 amino acids that binds DNA at consensus recognition sequences known as CArG boxes [CC(A/T)₆GG]. The interaction with DNA has been studied in detail for the human and yeast MADS-box proteins thanks to the resolved crystal structures. The I domain is less conserved and contributes to the specification of dimerization. The K domain is characterized by a coiled-coil structure, which facilitates the dimerization of MADS-box proteins. The C domain is the least conserved domain; in some cases, it has been shown to contain a transactivation domain or to contribute to the formation of multimeric MADS-box protein complexes.

This family includes genes such as AG, AGL15, ANR1, AP1, AP3, CAL, FLC, FUL, PI, SEP1, SEP2, SEP3, SHP1, SHP2, SOC1, SVP (Parenicová et al).

-   -   WRKY (involved in defence response and immunity). The WRKY         family proteins contain one or two highly conserved WRKY domains         characterized by the hallmark heptapeptide WRKYGQK and a         zinc-finger structure distinct from other known zinc-finger         motifs. To regulate gene expression, the WRKY domain binds to         the W box in the promoter of the target gene to modulate         transcription. In addition to the W box, a recent study         indicates that the WRKY domain may also bind to SURE, a sugar         responsive cis element, as a transcription activator. Members of         the WRKY superfamily from the Arabidopsis genome are classified         into three groups. Members of Group 1 typically contain two WRKY         domains, while most proteins with one WRKY domain belong to         Group 2. Group 3 proteins also have a single WRKY domain, but         the pattern of the zinc-finger motif is unique (Zhang et al).     -   ARF-Aux/IAA (involved in auxin responses, development and floral         meristem patterning). Aux/IAA proteins are short-lived nuclear         proteins that repress expression of primary/early auxin response         genes in protoplast transfection assays. Repression is thought         to result from Aux/IAA proteins dimerizing with auxin response         factor (ARF) transcriptional activators that reside on         auxin-responsive promoter elements, referred to as AuxREs. Most         Aux/IAA proteins contain four conserved domains, designated         domains I, II, III, and IV. Domain II and domains III and IV         play roles in protein stability and dimerization, respectively         domain I in Aux/IAA proteins may be an active repression domain         that is transferable and dominant over activation domains. An         LxLxL motif within domain I is important for conferring         repression. The dominance of Aux/IAA repression domains over         activation domains in ARF transcriptional activators provides a         plausible explanation for the repression of auxin response genes         via ARF-Aux/IAA dimerization on auxin-responsive promoters.

This family includes genes such as AXR2, AXR3, ETT, MP, NPH4, SHY2. (Tiwari et al)

-   -   Dof (involved in seed germination, endosperm-specific         expression, and carbon metabolism. This family includes genes         such as DAG1 (Yanagisawa et al).     -   Heat shock transcription factors (Hsfs) that act by binding to a         highly conserved palindromic heat shock response sequence in the         promoters of the target genes. In addition to mediating the         response to heat stress, Hsfs are thought to be involved in         cellular responses to oxidative stress, heavy metals and other         stress responses. It is known that the basic structure of Hsfs         and of their promoter recognition site is conserved throughout         the eukaryotic kingdom. Hsfs have a modular structure with a         highly conserved N-terminal DNA binding and a C-terminal         activation domain. Other conserved domains include an         oligomerisation domain, a nuclear localisation sequence and a         nuclear export sequence. Thus, Hsfs are easily recognised by         their conserved motifs essential for their function as         transcription factors. Plant Hsfs are divided into three groups         A, B and C (see WO2008/110848).

A skilled person would know that the application is applicable to any transcription factor, specifically any plant transcription factor. A skilled person would also know that many of the families as listed above have homologues and orthologues in other plant species. Any transcription factor within those families above or a homologue and orthologue thereof may be used according to the various aspects of the invention.

Plant transcription factors regulate many developmental and physiological processes and by using the constructs and methods of the invention, these may be altered through constitutive expression of the selected transcription factors involved in said process. Preferably, the transcription factor is involved in the regulation of pathways of agronomic interest. These pathways may concern plant morphology, physiology, growth, development, yield, control of metabolism, nutritional profile, stress resistance, such as disease or pest resistance, and/or environmental or chemical tolerance. Expression of the constructs described herein and the methods of the invention may therefore be used to enhance or confer a beneficial trait compared to a control plant, for example a wild type plant, which does not express the expression construct or vector according to the invention which has been introduced as a transgene into said organism.

A beneficial trait may be, but is not limited to: increased growth/yield, herbicide tolerance, insect control, fungal disease resistance, virus resistance, nematode resistance, bacterial disease resistance, modified plant development, starch production, modified oil production, modified fatty acid content, modified fruit ripening, enhanced value for animal and human nutrition, environmental stress resistance, improved flavour, increased seed storage protein content, modified plant architecture, increased root formation, modified metabolite content or improved nitrogen fixation. Developmental and physiological processes that may be targeted to achieve a benefit include: root formation, flowering time, seed development, senescence, metabolite production, hormone production/signalling or stress tolerance. Stress tolerance may be tolerance again biotic or abiotic stress, for example draught, pathogen invasion, cold, freezing, deficit of nutrients in the soil, heat or other types of stress.

In one embodiment, the beneficial trait relates to an improvement of root architecture. Improved root architecture may be selected from a non exclusive list of altered diameter, length, weight, number, angle or surface of one or more of the root system parts, including but not limited to, the primary root, lateral or branch root, adventitious root, and root hairs, all of which fall within the scope of this invention. These changes may lead to an overall alteration in the area or volume occupied by the root. In one embodiment, growth of root hairs is altered. This is achieved by constitutive expression of an expansin gene, for example EXP7. Expansin refers to a family of closely related nonenzymatic proteins found in the plant cell wall, with important roles in plant cell growth, fruit softening, abscission, emergence of root hairs, pollen tube invasion of the stigma and style, meristem function, and other developmental processes where cell wall loosening occurs. Where a feature is of the root is increased, the increase may be at least 10%, at least 20%, at least 30%, at least 40%, at least 50% or more. In one embodiment, the altered root phenotype is increased or length. The increase may be at least 10%, at least 20%, at least 30%, at least 40%, at least 50% or more. In one embodiment, then total mass/weight of the root is increased. The increase may be at least 10%, at least 20%, at least 30%, at least 40%, at least 50% or more.

The root phenotype is altered compared to a control plant. A control plant as used according to the different aspects of the invention is a plant, which has not been modified according to the methods of the invention. Accordingly, the control plant has not been genetically modified to express a nucleic acid as described herein to alter the root phenotype. In one embodiment, the control plant is a wild type plant. In another embodiment, the control plant is a plant that does not carry a transgenic according to the methods described herein, but expresses a different transgene. The control plant is typically of the same plant species, preferably the same ecotype as the plant to be assessed.

The term “yield” as described herein relates to yield-related traits. Specifically, these include an increase in biomass and/or seed yield. This may be achieved by increased growth. An increase in yield may be, for example, assessed by the harvest index, i.e. the ratio of seed yield to aboveground dry weight. Thus, according to the invention, yield may comprise one or more of: increased seed yield per plant, increased seed filling rate, increased number of filled seeds, increased harvest index, increased number of seed capsules/pods, increased seed size, increased growth or increased branching, for example inflorescences with more branches. Preferably, yield may comprise an increased number of seed capsules/pods and/or increased branching. Yield is increased relative to control plants. An increase in yield may be about 5, 10, 20, 30, 40, 50% or more compared to a control plant. A control plant is a plant that does not express a construct or vector as described herein. The plant may be a wild type plant or a plant which has been genetically modified in another way.

The plant transcription factor gene may be selected from any of the examples in table. 1. In one embodiment, the plant transcription factor gene may for example be selected from RSL4, SND, GL1, MP, ARF7, AGL28, Cr1, WRI1, Opaque2, KN, OCL1, DREB1 or a homologue or orthologue thereof. In one embodiment, the plant transcription factor gene is RSL4 (SEQ ID NO. 2) or a homologue or orthologue thereof. Thus, any ROOT HAIR DEFECTIVE 6 (RHD6)-related gene or RHD6 may be used. RHD6-related genes include genes capable of complementing the rhd6 mutation in plants. Thus, the RSL4 homologue or orthologue thereof may be selected from any of the nucleic acid/amino acid sequences SEQ ID No. 5 to 117. RSL4 or a homologue or orthologue thereof are disclosed in WO 2008/142364. RSL4 or any homologue or orthologue may be expressed using EXP7.

The plant promoter may be selected from any promoter which is a promoter of a downstream target gene of the transcription factor selected. In a preferred embodiment, the promoter is a tissue or organ specific promoter. In another preferred embodiment, the promoter is developmentally regulated.

A preferred tissue-specific or developmentally regulated promoter is a DNA sequence which regulates the expression of a DNA sequence selectively in the cells/tissues of a plant critical to tassel development, seed set, or both, and limits the expression of such a DNA sequence to the period of tassel development or seed maturation in the plant. Any identifiable promoter may be used in the aspects of the present invention which causes the desired temporal and spatial expression.

The promoter may be specific to any organ of the plant, including reproductive organs and a non-limiting list includes roots, including parts thereof such as root trichomes, seeds, stems, leaves, fruits, flowers or parts thereof, stems, rhizomes, tubers, embryos and bulbs. The promoter may direct tissue specific expression, for example expression in meristems, parenchyma, collenchyma or sclerenchyma.

Promoters which are seed or embryo specific and may be useful in the invention include soybean Kunitz trysin inhibitor, patatin (potato tubers), convicilin, vicilin, and legumin (pea cotyledons), zein (maize endosperm), phaseolin (bean cotyledon), phytohemagglutinin (bean cotyledon), B-conglycinin and glycinin (soybean cotyledon), glutelin (rice endosperm), hordein (barley endosperm), glutenin and gliadin (wheat endosperm) and sporamin (sweet potato tuberous root).

Plant root systems are essential for crops to capture water and nutrients for growth and yield. There is a positive correlation between the size of the plant root system and greater capture of water and nitrogen and grain-fill. In many environments, water uptake may be a limiting factor for crop yield. Thus, in another embodiment, a root-specific promoter may be used. This is a promoter that is transcriptionally active predominantly in plant roots, substantially to the exclusion of any other parts of a plant, whilst still allowing for any leaky expression in these other plant parts. Examples of promoters specific to roots or part thereof according to the various aspects of the invention include promoters of root expressible genes, for example the promoters of the following genes: RCc3, Arabidopsis PHT1, Medicago phosphate transporter, Arabidopsis Pyk10, tobacco auxin-inducible gene, beta-tubulin, LRX1, ALF5, EXP7, LBD16, ARF1, tobacco RD2, S1REO, Pyk10, PsPR10.

Root hairs play important roles in plant nutrition and water uptake. In most soils they are important for phosphate and iron uptake. In drought conditions they are important in the uptake of other nutrients such as nitrate. Therefore the manipulation of root hair traits will be important in developing crops that may effectively extract nutrients from the soil. In one embodiment, the promoter is specific to root hairs. In a preferred embodiment, the promoter is EXP7 (SEQ ID NO. 1).

One non-limiting embodiment of the first expression according to the various aspects of the invention is shown in example 1. This shows an expression construct (EXP7pro-RSL4) which enables constitutive expression of the plant transcription factor RSL4 in root hairs cells through a positive feedback loop. This in turn activates expression of the RSL4 downstream target EXP7. The construct is expressed in root hair cells where RSL4 is naturally expressed. The introduction and expression of the expression construct results in constitutive expression of RSL4. This in turn increases expression of the downstream target gene EXP7. Transgenic plants expressing said construct develop longer root hairs compared to wild type plants.

Other non-limiting examples of genes and constructs that are within the scope of the various aspects of the invention are set out in table 2. A skilled person would appreciate that homologues and orthologues in other plants may be used.

Table 2. Non-Limiting Examples of Genes and Constructs

1. Expression of SND in Fibre Cells (Arabidopsis thaliana)

-   -   SND is a transcription factor that positively regulates the         expression of MYB64 in fibre cells (Zhong et al 2007).     -   TART construct for constitutive expression in fibre cells:         MYB46promoter:SND1     -   Expected phenotypic consequences: Thinning of cell walls (Zhong         et al 2007b).         2. Expression of GL1 in Trichome Cells (Arabidopsis thaliana)     -   GL1 is a transcription factor that positively regulates the         expression of MYC1, SCL8, SIM and RBR1 genes in trichomes         (Morohashi and Grotewold 2010).     -   TART constructs for constitutive expression in trichomes:         -   MYC1promoter:GL1         -   SCL8promoter:GL1         -   SIMpromoter:GL1         -   RBR1promoter:GL1     -   Expected phenotypic consequences: Reduction in trichomes number.         3. Constitutive Expression of MP in Embryos (Arabidopsis         thaliana)     -   MP is a transcription factor that positively regulated the         expression of TMO5 and TMO7 in embryos (Schlereth et al. 2010).     -   TART constructs for constitutive expression in embryos:         -   TMO5promoter:MP         -   TMO7promoter:MP     -   Expected phenotype: Architectural variation         4. Constitutive Expression of ARF7 in Lateral Roots (Arabidopsis         thaliana)     -   ARF7 is a transcription factor that positively regulates the         expression of LBD16 and LBD18 in lateral roots (Okushima et al         2007).     -   TART constructs for constitutive expression in lateral roots:         -   LBD16promoter:ARF7         -   LBD18promoter:ARF7     -   Expected phenotypic consequences: Increase in the number of         lateral roots (Okushima et al 2007).         5. Constitutive Expression of AGL28 Promotes Flowering         (Arabidopsis thaliana)     -   Constitutive expression of AGL28 promotes flowering by         positively regulating expression of FCA and LD.     -   TART constructs for constitutive expression of AGL28:         -   FCApromoter:AGL18         -   LDpromoter:AGL18     -   Expected phenotype: modified flowering time.

6. Constitutive Expression of Cr1 During Crown Root Formation in Rice

-   -   OsARF1 positively regulates Cr1 during crown root formation in         rice (Inukaki et al 2005).     -   TART construct for constitutive expression of OsARF1:         -   Cr1promoter:OsARF1     -   Phenotypic consequences: increase in crown root number.

7. Constitutive Expression of WRI1a in Maize Kernels

-   -   WRI1a controls the expression of the following maize genes:     -   MZ00042142, MZ00024552, MZ00043500, MZ00024718, MZ00016632,         MZ00014741, MZ00043050, MZ00056535, MZ00017651, MZ00016866,         MZ00017355, MZ00040095, MZ00042163, MZ00016943, MZ00044044,         MZ00026553, MZ00015977, MZ00031529, MZ00039375 (Pouvreau et al         2011)     -   TART constructs for constitutive expression of WR1a:         -   MZ00042142promoter:WRI1a         -   MZ00024552promoter:WRI1a         -   MZ00043500promoter:WRI1a         -   MZ00024718promoter:WRI1a         -   MZ00016632promoter:WRI1a         -   MZ00014741promoter:WRI1a         -   MZ00043050promoter:WRI1a         -   MZ00056535promoter:WRI1a         -   MZ00017651promoter:WRI1a         -   MZ00016866promoter:WRI1a         -   MZ00017355promoter:WRI1a         -   MZ00040095promoter:WRI1a         -   MZ00042163promoter:WRI1a         -   MZ00016943promoter:WRI1a         -   MZ00044044promoter:WRI1a         -   MZ00026553promoter:WRI1a         -   MZ00015977promoter:WRI1a         -   MZ00031529promoter:WRI1a         -   MZ00039375promoter:WR1a     -   Expected phenotype: increases in palmitic acid, succinic acid,         linolenic acid, lysine, oleic acid, glyceric acid, stearic acid,         citric acid, glutamic acid phosphoric acid, phenylalanine,         arabinose, linoleic acid, pyroglutamic acid, norleucine,         nicotinic acid, alanine, valine, aminoadipic acid, ornithine         content.

8. Constitutive Expression of Opaque2 in Maize Endosperm

Opaque2 controls CyPPDK1 22 kd zein proteins encoding genes and p32 protein encoding genes in maize endosperm (Gallusci et al 1996; Maddoloni et al 1996).

-   -   TART constructs for constitutive expression of Opaque2:         -   CyPPDK1promoter:Opaque2         -   Zeinpromoter:Opaque2         -   Protein32promoter:Opaque2     -   Expected phenotype: increased seed storage protein content.

9. Constitutive Expression of Knotted (KN) Gene in Maize Meristems

-   -   KN1 gene positively regulates the expression of GA2OX1 in maize         (Bolduc and Hake, 2009).     -   TART constructs for constitutive expression of KN1 in maize:         -   GA2OX1promoter:KN1     -   Expected phenotype: modified shoot architecture

10. Constitutive Expression of OCL1 in Maize

-   -   OCL1 positively regulated the expression of ZmWBC11b, ZmWBC11c,         ZmLtpII.12, ZmFAR1, MZ00030315, MZ00029474, MZ00022171, and         MZ00031955 (Javelle et al 2010).     -   TART constructs for constitutive expression of OCL1 in maize:         -   ZmWBC11b:promoterOCL1         -   ZmWBC11c:promoterOCL1         -   ZmLtpII.12:promoterOCL1         -   ZmFAR1:promoterOCL1         -   MZ00030315:promoterOCL1         -   MZ00029474:promoterOCL1         -   MZ00022171:promoterOCL1         -   MZ00031955:promoterOCL1     -   Expected phenotype: Modified cuticle and kernel.

11. Constitutive Expression of DREB1 in Rice

-   -   DREB1 positively regulates the expression of J033041J03,         J013078A14, 001-120-D04, J013091D15, J023041L05, J023082D02,         J013097O21, 001-125-G03, 001-104-B03, 001-023-B08, J023121A17         and J023042N13 genes in rice (Ito, et al., 2006).     -   TART constructs for constitutive expression of DREB1 in rice         -   J033041J03:promoterDREB1         -   J013078A14:promoterDREB1         -   001-120-D04:promoterDREB1         -   J013091D15:promoterDREB1         -   J023041L05:promoterDREB1         -   J023082D02:promoterDREB1         -   J013097021:promoterDREB1         -   001-125-G03:promoterDREB1         -   001-104-B03:promoterDREB1         -   001-023-B08:promoterDREB1         -   J023121A17:promoterDREB1         -   J023042N13:promoterDREB1     -   Expected phenotype: enhanced stress resistance.

Thus, any construct disclosed in table 2 may be used according to the different aspects and embodiments of the invention described herein.

In another aspect, the invention relates to a vector which may comprise a first expression construct as described herein. As used herein, the term “vector” refers to a nucleic acid construct designed for transfer between different host cells. It has the ability to incorporate and express heterologous DNA fragments in a foreign cell. Many prokaryotic and eukaryotic expression vectors for expression in different organisms are commercially available. Selection of appropriate expression vectors is within the knowledge of those having skill in the art. The vector may also comprise further elements that aid in the methods of the invention, for example marker genes for selection.

In one embodiment, the vector, for example a binary vector, further may comprise a second expression construct. Use of this vector in the methods of the invention as explained below allows for expression of the selected transcription factor in a cell, tissue or organ in which it is not normally expressed in vivo and/or under conditions under which it is not normally expressed in vivo.

The second expression construct may comprise a first nucleic acid sequence encoding a transcription factor; this is substantially the same sequence as used in the first expression construct. Further, it may comprise a second isolated promoter nucleic acid sequence operably linked to the first nucleic acid sequence encoding a transcription factor. The promoter sequence used in the second construct is distinct from that used in the first construct. However, the transcription factor nucleic acid sequence is substantially the same as the transcription factor nucleic acid sequence used in the first construct. In the organism from which said second promoter sequence is derived, the promoter directs the expression of a gene in a specific cell, tissue or organ in which the transcription factor gene used in the expression construct is not normally expressed and/or the conditions under which the transcription factor gene is not normally expressed in said organism. Therefore, in the second expression construct, the isolated nucleic acid sequence encoding the transcription factor gene is operably linked to a different promoter than in the first construct. In contrast to the first promoter sequence used, the second promoter is not specific to the cell, tissue or organ in which the transcription factor gene is normally expressed and/or the conditions under which the transcription factor gene is normally expressed. Methods using the vector which may comprise the two expression constructs may therefore ensure constitutive expression of a transcription factor gene in a cell, tissue or organ in which the transcription factor gene is not normally expressed.

As explained elsewhere, the transcription factor nucleic acid sequence and the promoter sequence may be of plant, animal or bacterial origins. In a preferred embodiment, the transcription factor nucleic acid sequence and the promoter sequence are of plant origin.

In one embodiment, the promoter of the first construct is specific to root hairs. In a preferred embodiment, the promoter is EXP7 (SEQ ID NO. 1). In one embodiment, the transcription factor gene is RLS4 (SEQ ID No. 2). In one embodiment, the promoter is EXP7 (SEQ ID NO. 1) and the transcription factor gene is RLS4 (SEQ ID No. 2). In one embodiment, the second promoter is GL2. (SEQ ID No. 3). Orthologues and homologues of RSL4 selected from SEQ ID No. 5-117 may also be used.

The first and second expression construct as described herein may be used, either as part of a single vector or by using separate vectors for the expression of the first and second expression construct respectively, in the methods for constitutive expression of a transcription factor in a desired cell, tissue, organ and/or conditions according to the methods of the invention. Transformation of an organism, for example a plant, with such vector(s) allows constitutive expression of the transcription factor in a cell, tissue or organ that normally does not express this transcription factor gene. Thus, once transcription factor expression is initiated from the first expression construct in the desired cell, tissue, organ and/or under the desired conditions, this activates expression of the transcription factor from the second expression construct. Constitutive expression is thus achieved via a positive feedback loop. Accordingly, constitutive expression of genes that encode desirable gene products may thus be achieved in the desired location due to constitutive expression of the transcription factor which in turn activates expression of downstream target genes. For example, if the transcription factor controls the accumulation of secondary metabolites, the use of the two expression constructs as described may both elevate levels of metabolite production and/or target their production to certain cell types.

The present invention also relates to an isolated host cell which may comprise an expression construct or vector of the present invention. In one embodiment, the host cell is a plant cell. For example, a heterologous nucleic acid construct or vector as described herein is introduced into the genome of a plant host cell by transfection, for example with Agrobacterium tumefaciens for plant transformation, microinjection, electroporation, biobalistics or the like.

The invention also relates to a transgenic prokaryotic or eukaryotic organism which has been transformed with the expression construct or vector of the invention and thus expresses the transgene(s). Thus, in one aspect, the invention relates a transgenic organism, for example a plant, which constitutively expresses an endogenous transcription factor gene of interest and wherein said transcription factor is expressed in the same cell, tissue or organ in which it is normally expressed and/or conditions under which it is normally expressed, but at a constitutive level compared to the level of expression in a control organism that does not express the transgene.

In another aspect, the invention relates to a transgenic organism, for example a plant, which constitutively expresses an endogenous transcription factor gene of interest and wherein said transcription factor is expressed in a cell, tissue or organ in which it is not normally expressed and/or conditions under which it is not normally expressed, at a constitutive level compared to the level of expression in a wild type organism that does not express the transgene. As used herein, the terms “transformed”, “stably transformed” or “transgenic” with reference to host organism mean that the transgene is stably integrated within the host genome such that the polynucleotide is passed on to successive generations. Thus, the expression construct(s) and vector(s) described herein may be expressed in a host organism using recombinant DNA technology. Thus, the host organism is transgenic in respect of the expression construct as it may comprise within its genome a heterologous DNA segment. A transgenic plant for the purposes of the invention is thus understood as meaning, as above, that the nucleic acids used in the method of the invention are not at their natural locus in the genome of said plant, it being possible for the nucleic acids to be expressed homologously or heterologously.

A preferred host organism is a plant or part thereof. The term part thereof includes reference to plant organs (for example, leaves, stems, roots, seeds etc.) and plant cells and their progeny and any material that may be harvested from a plant. The term “plant cell”, as used herein includes, without limitation, cells form the following tissues/organs seeds, embryos, meristematic regions, callus tissue, leaves, roots. Also included are gametophytes, sporophytes, pollen, and microspores. Further included are cells in in vitro suspension cultures.

The term “plant” according to the different aspects of the invention includes both monocotyledenous and dicotyledenous plants. In one embodiment, the plant is a dicot plant. A dicot plant may be selected from the families including, but not limited to Asteraceae, Brassicaceae (eg Brassica napus), Chenopodiaceae, Cucurbitaceae, Leguminosae (Caesalpiniaceae, Aesalpiniaceae Mimosaceae, Papilionaceae or Fabaceae), Malvaceae, Rosaceae or Solanaceae. For example, the plant may be selected from lettuce, sunflower, Arabidopsis, broccoli, spinach, water melon, squash, cabbage, tomato, potato, capsicum, tobacco, cotton, oilseed rape, okra, apple, rose, strawberry, alfalfa, bean, soybean, field (fava) bean, pea, lentil, peanut, chickpea, apricots, pears, peach, grape vine or citrus species. In one embodiment, the plant is tobacco. In one embodiment, the plant is barley. In one embodiment, the plant is soybean. In one embodiment, the plant is cotton. In one embodiment, the plant is maize (corn). In one embodiment, the plant is rice. In one embodiment, the plant is oilseed rape including canola. In one embodiment, the plant is wheat. In one embodiment, the plant is sugarcane. In one embodiment, the plant is sugar beet.

In one embodiment, the plant is a dicot plant. A monocot plant may, for example, be selected from the families Arecaceae, Amaryllidaceae or Poaceae. For example, the plant may be a cereal crop, such as wheat, rice, barley, maize, oat, sorghum, rye, onion, leek, millet, buckwheat, turf grass, Italian rye grass, switchgrass, Miscanthus, sugarcane or Festuca species.

Preferably, the plant is a crop plant. By crop plant is meant any plant which is grown on a commercial scale for human or animal consumption or use or other non-food/feed use. Non limiting examples of crop plants include soybean, beet, sugar beet, sunflower, oilseed rape including canola, chicory, carrot, cassaya, alfalfa, trefoil, rapeseed, linseed, cotton, tomato, potato, tobacco, poplar, eucalyptus, pine trees, sugarcane and cereals such as rice, maize, wheat, barley, millet, rye, triticale, sorghum, emmer, spelt, secale, einkorn, teff, milo and oats.

Preferred plants are tobacco, maize, wheat, rice, oilseed rape, sorghum, soybean, potato, tomato, barley, pea, bean, cotton, field bean, lettuce, broccoli or other vegetable brassicas or poplar. In another embodiment the plants of the invention and the plants used in the methods of the invention are selected from the group consisting of maize, rice, wheat, soybean, cotton, oilseed rape including canola, sugarcane, sugar beet and alfalfa.

Also included are biofuel and bioenergy crops such as rape/canola, linseed, lupin and willow, poplar, poplar hybrids, switchgrass, Miscanthus or gymnosperms, such as loblolly pine. Also included are crops for silage (maize), grazing or fodder (grasses, clover, sanfoin, alfalfa), fibres (e.g. cotton, flax), building materials (e.g. pine, oak), pulping (e.g. poplar), feeder stocks for the chemical industry (e.g. high erucic acid oil seed rape, linseed) and for amenity purposes (e.g. turf grasses for golf courses), ornamentals for public and private gardens (e.g. snapdragon, petunia, roses, geranium, Nicotiana sp.) and plants and cut flowers for the home (African violets, Begonias, chrysanthemums, geraniums, Coleus spider plants, Dracaena, rubber plant). In another embodiment, the invention relates to trees, such as poplar or eucalyptus trees.

In another aspect, the invention relates to a method for constitutive expression of a transcription factor gene in a host cell or organism. Constitutive expression is compared to expression in a control organism, for example a wild type organism, which does not express the transgene (the expression construct according to the various aspects of the invention). The method may comprise transforming the host cell or organism with an expression construct(s) or vector(s) as described herein which may comprise a nucleic acid sequence encoding a transcription factor operably linked to an isolated promoter nucleic acid sequence of a target gene wherein said transcription factor regulates expression of said target gene. The transgene is stably integrated into the genome of the host cell or organism and thus expressed in the host cell or organism. Preferably, the transcription factor encoding gene is a gene that is normally expressed in a particular cell type, tissue or organ of said organism and/or under specific conditions. Accordingly, in the transformed organism which expresses the transgene, the transcription factor is constitutively expressed in the cell, tissue or organ in which it is normally expressed through a positive feedback loop (see FIG. 3).

Thus, the transgene or expression construct which is described herein and may comprise a transcription factor encoding gene that is normally expressed in a particular cell type is placed under the control of a promoter of a downstream target gene (see FIG. 1). This construct is then transformed into the host organism. The transcription of the transgene is activated when the endogenous transcription factor gene is expressed and activates transcription of the target promoter. The expression of the transcription factor gene from the transgene in turn activates the expression of the target promoter in the transgene, resulting in still further expression of the transgene. In other words, the transcription factor gene encoded by the construct positively regulates its own transcription. Therefore, once the endogenous transcription factor gene is expressed, this initiates a positive feedback loop that leads to the constitutive expression transcription factor gene from transgene.

The organism may be prokaryotic or eukaryotic as described herein. For example, the organism may be a bacterium, yeast, an animal or preferably a plant. In a preferred embodiment, the organism is a plant. The nucleic acid sequence encoding a transcription factor is a sequence which is endogenous to said organism but which has been operably linked to a promoter sequence that does not usually control expression of the transcription factor gene. Preferably, the invention does not relate to the use of an exogenous nucleic acid sequence encoding a transcription factor. An exogenous sequence is a sequence that does not usually occur in said organism.

In one embodiment, the invention relates to a method for constitutive expression of a plant transcription factor gene in a transgenic plant. The method may comprise transforming a plant with an expression construct or vector as described herein which may comprise a plant transcription factor nucleic acid sequence operably linked to a plant promoter gene sequence wherein said promoter sequence is derived from a plant promoter sequence of a target plant gene of said transcription factor and wherein said transcription factor regulates expression of said target gene. Example 1 shows constitutive expression of the plant transcription factor RSL4 in root hairs using a promoter which drives the expression of the EXP7 gene in plants (EXP7pro-RSL4 construct).

In one embodiment, the transcription factor nucleic acid sequence encodes a transcription factor that is normally expressed in a specific plant tissue or organ and not in the whole plant. In one embodiment, the transcription factor nucleic acid sequence encodes a transcription factor that is normally expressed under specific conditions, such as specific environmental conditions.

Accordingly, because expression of the transcription factor gene is driven by a tissue/organ specific promoter that is the promoter of a downstream target gene of said transcription factor, the transcription factor gene is constitutively expressed in those cells or tissue where it is normally expressed as expression of the transcription factor from the transgene regulates its own expression as the transcription factor encoded by the transgene binds directly or indirectly to the promoter of the transgene to stimulate expression.

In another aspect, the invention relates to a method for constitutive expression of a transcription factor gene in a cell, tissue or organ in which it is not normally expressed. The method may comprise introducing two expression constructs into said organism is as described herein. These may be introduced by using a single vector which may comprise both constructs or by using two vectors. For example, the organism may be transformed with the first vector to generate stable homozygous lines. In a second step, the organism which expresses said first transgene is transformed with the second expression construct, thus generating stable transgenic lines that are homozygous for both transgenes. Alternatively, a first organism may be transformed with the first vector which may comprise a first expression construct to generate stable homozygous lines. A second organism is transformed with the second vector which may comprise a second expression construct to generate stable homozygous lines. Stable homozygous lines derived from the first and second organism are crossed to generate stable homozygous offspring expressing both transgenes.

The first expression construct used in these methods is as described herein and may comprise a nucleic acid sequence encoding a transcription factor operably linked to a promoter sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene. The second expression construct may comprise a nucleic acid sequence encoding a transcription factor as in the first construct. However, in the second construct, a nucleic acid sequence encoding a transcription factor is operably linked to a promoter of a gene that is active in desired cell, tissue or organ. As explained above, this leads to a cascade of gene expression in the target tissue.

In one embodiment of this method, the invention relates to a method for constitutive expression of a transcription factor gene in a plant cell, tissue or organ in which it is not normally expressed. Therefore, expression of the transcription factor may be in any plant vegetative or reproductive tissue of interest. In order to achieve stable expression of the transgenic in the plant, a plant may be transformed with both constructs and stable transformants in which the transgenes have been integrated into the genome and are expressed are selected according to methods in the art. Alternatively, a first plant is transformed with the first construct and a second plant is transformed with the second construct. Stable transformants are selected and crossed to achieve co-expression of both constructs. Example 2 shows constitutive expression of GL2:RSL4 and EXP7pro-RSL4 in plants.

Also within the scope of the invention are transgenic cells and organisms obtained or obtainable by the methods of the invention.

Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined in the appended claims.

The present invention will be further illustrated in the following Examples which are given for illustration purposes only and are not intended to limit the invention in any way.

EXAMPLES Example 1 Expression of EXP7pro-RSL4 in Plants

The RSL4 gene controls the expression of the EXP7 gene during root hair development and the promoter of EXP7 is sufficient to drive root hair cell specific gene expression (Keke et al, 2010). We constructed an EXP7:RSL4 gene fusion and transformed Arabidopsis thaliana (EXP7 is the target promoter (TAR) and RSL4 is the upstream transcription factor (T)).

Constructs for Expression of RSL4

A fusion of the EXP7 promoter and the RSL4 coding sequence was made. This is represented here.

EXP7 Promoter (in Bold)::RSL4 (Underlined)

gagctcgtagttagatgattacaaaggggaaatttaggttaaaagcgtttttttttattctgagtaaaatttgggaatagctttaga ttgtggggttacagataaagtagagctatgtgttagtaaaagtctttgtggtagtgacttgtgataatatttattgttacaggtaag tgggaagagagttgggatagttggattggggagcattggatcatttgttgctaaaagacttgaatcatttggctgtgttatctct tacaactcaaggagtcagaaacagagtagtccataccggtattactctgacattctctcgttagcagagaacaacgatgtact tgtcctctgctgctctttgacagacgaaacgcaccatattgtgaatagagaagtgatggagttgcttggtaaggatggggttg tgatcaatgtgggacgaggaaagttgattgatgagaaggagatggtcaagtgtttggttgacggtgtgattggtggtgctgg tttagatgtgtttgagaatgaaccggcagttcctcaggagttgtttggtttggataatgtagtgttgtctcctcattttgctgtggct acaccagggtctttggacaatgttgcacagattgctttagctaacttgaaggcgtttttctcgaaccggcctttgctttctccggt tcaattggattgagagagcgcccggtttgatcaggtagctaaattagttaagctattgtttattataatcaataattcaaaaagaa agtgtaatgaatatttgaatgtaccctgacattctctcccaaagaagaagaattaatgacgcatattatttaaataattctcccgc gttgcacatatgactaatttagtcggaacattacgattggcaatataatcataatgtttatgaataaccttttggttctaatgttatt gtgaaaatactgttaaaacatgatttcatatattagtttatctttggaaacgtaaatagttgacaaacgacaatataaaaataaat gtctgctgttcaatttaactaatcattgaaaatacataaacgcacgtatatatagacattggatagagtcggtacacgtatcgtc tatagaacctgctcgcacgtcaacttatactatattcaaaaacctcacttaaacaacaattgaccttttttcctaaattttattagta tttctattgaaaaaattcaatgaaatgaaacaaatcccaatcggtacggacaaaagtctccaataaaaaaggaattaaaaaaa aaaaggatagtgatccgcacgtagccaccactactgtcgttgaaaatcccctctatataagattgtctcaaattcgattacttca tcaaaaaacaaaccaaaaacaaaccctaagaataaagaaaaagaggctagaatgggtccggtaccCATGGACGT TTTTGTTGATGGTGAATTGGAGTCTCTCTTGGGGATGTTCAACTTTGATCA ATGTTCATCATCTAAAGAGGAGAGACCGCGAGACGAGTTGCTTGGCCTCT CTAGCCTTTACAATGGTCATCTTCATCAACATCAACACCATAACAATGTCT TATCTTCTGATCATCATGCTTTCTTGCTCCCTGATATGTTCCCATTTGGTGC AATGCCGGGAGGAAATCTTCCGGCCATGCTTGATTCTTGGGATCAAAGTC ATCACCTCCAAGAAACGTCTTCTCTTAAGAGGAAACTACTTGACGTGGAG AATCTATGCAAAACTAACTCTAACTGTGACGTCACAAGACAAGAGCTTGC GAAATCCAAGAAAAAACAGAGGGTAAGCTCGGAAAGCAATACAGTTGAC GAGAGCAACACTAATTGGGTAGATGGTCAGAGTTTAAGCAACAGTTCAGA TGATGAGAAAGCTTCGGTCACAAGTGTTAAAGGCAAAACTAGAGCCACC AAAGGGACAGCCACTGATCCTCAAAGCCTTTATGCTCGGAAACGAAGAG AGAAGATTAACGAAAGGCTCAAGACACTACAAAACCTTGTGCCAAACGG GACAAAAGTCGATATAAGCACGATGCTTGAAGAAGCGGTCCATTACGTGA AGTTCTTGCAGCTTCAGATTAAGTTGTTGAGCTCGGATGATCTATGGATGT ACGCACCATTGGCTTACAACGGGCCTGGACATGGGGTTCCATCACAACCT TTTGTCTCGGCTTATGTGAggatcctctagagtcgacctgcaggcatgcaagcttT

This fusion was then ligated into SacI/KpnI-digested pCambia1300 vector (Hajdukiewicz, P et al 1994 The small pPZP family of Agrobacterium binary vectors for plant transformation Plant Molecular Biology 25, 989-994) or any similar vector.

Plant Transformation and Generation of Homozygous Lines Expressing the Transgene

The EXPpro7:RSL4 transgene was transformed into Arabidopsis thaliana plants. Hygromicin-resistant transformants were selected. Self pollinated lines were selected for plants that were either hemizygous or homozygous for the transgene.

Results

Plants transformed with EXP7:RSL4 had elevated levels of expression of RSL4 transcription indicating that RSL4 is constitutively expressed in root hairs. The root hairs of plants transformed with EXP7-RSL4 grow constitutively until they die and therefore develop very long root hairs (see FIG. 5). This phenotype is identical to that found on roots that constitutively express RSL4 using the CaMV35S promoter (see FIG. 6). Together these data indicates that EXP7:RSL4 results in the constitutive expression of RSL4 in root hair cells.

Without wishing to be bound by theory, we believe that RSL4 positively regulated EXP7 indirectly. That is we think that RSL4 binds to the promoter of another gene that encodes a proteins that in turn binds to the EXP7 promoter.

Example 2 Expression GL2:RSL4 and Expression of GL2:RSL4 and EXP7pro-RSL4 in Plants

Constructs for Expression of GL2:RSL4 and Expression of GL2:RSL4 and EXP7pro-RSL4 in Plants

A fusion of the EXP:7 promoter and the RSL4 coding sequence is made. This is represented here.

EXP7 Promoter (in Bold)::RSL4 (Underlined)

gagctcgtagttagatgattacaaaggggaaatttaggttaaaagcgtttttttttattctgagtaaaatttgggaatagctttaga ttgtggggttacagataaagtagagctatgtgttagtaaaagtctttgtggtagtgacttgtgataatatttattgttacaggtaag tgggaagagagttgggatagttggattggggagcattggatcatttgttgctaaaagacttgaatcatttggctgtgttatctct tacaactcaaggagtcagaaacagagtagtccataccggtattactctgacattctctcgttagcagagaacaacgatgtact tgtcctctgctgctctttgacagacgaaacgcaccatattgtgaatagagaagtgatggagttgcttggtaaggatggggttg tgatcaatgtgggacgaggaaagttgattgatgagaaggagatggtcaagtgtttggttgacggtgtgattggtggtgctgg tttagatgtgtttgagaatgaaccggcagttcctcaggagttgtttggtttggataatgtagtgttgtctcctcattttgctgtggct acaccagggtctttggacaatgttgcacagattgctttagctaacttgaaggcgtttttctcgaaccggcctttgctttctccggt tcaattggattgagagagcgcccggtttgatcaggtagctaaattagttaagctattgtttattataatcaataattcaaaaagaa agtgtaatgaatatttgaatgtaccctgacattctctcccaaagaagaagaattaatgacgcatattatttaaataattctcccgc gttgcacatatgactaatttagtcggaacattacgattggcaatataatcataatgtttatgaataaccttttggttctaatgttatt gtgaaaatactgttaaaacatgatttcatatattagtttatctttggaaacgtaaatagttgacaaacgacaatataaaaataaat gtctgctgttcaatttaactaatcattgaaaatacataaacgcacgtatatatagacattggatagagtcggtacacgtatcgtc tatagaacctgctcgcacgtcaacttatactatattcaaaaacctcacttaaacaacaattgaccttttttcctaaattttattagta tttctattgaaaaaattcaatgaaatgaaacaaatcccaatcggtacggacaaaagtctccaataaaaaaggaattaaaaaaa aaaaggatagtgatccgcacgtagccaccactactgtcgttgaaaatcccctctatataagattgtctcaaattcgattacttca tcaaaaaacaaaccaaaaacaaaccctaagaataaagaaaaagaggctagaatgggtccggtaccCATGGACGT TTTTGTTGATGGTGAATTGGAGTCTCTCTTGGGGATGTTCAACTTTGATCA ATGTTCATCATCTAAAGAGGAGAGACCGCGAGACGAGTTGCTTGGCCTCT CTAGCCTTTACAATGGTCATCTTCATCAACATCAACACCATAACAATGTCT TATCTTCTGATCATCATGCTTTCTTGCTCCCTGATATGTTCCCATTTGGTGC AATGCCGGGAGGAAATCTTCCGGCCATGCTTGATTCTTGGGATCAAAGTC ATCACCTCCAAGAAACGTCTTCTCTTAAGAGGAAACTACTTGACGTGGAG AATCTATGCAAAACTAACTCTAACTGTGACGTCACAAGACAAGAGCTTGC GAAATCCAAGAAAAAACAGAGGGTAAGCTCGGAAAGCAATACAGTTGAC GAGAGCAACACTAATTGGGTAGATGGTCAGAGTTTAAGCAACAGTTCAGA TGATGAGAAAGCTTCGGTCACAAGTGTTAAAGGCAAAACTAGAGCCACC AAAGGGACAGCCACTGATCCTCAAAGCCTTTATGCTCGGAAACGAAGAG AGAAGATTAACGAAAGGCTCAAGACACTACAAAACCTTGTGCCAAACGG GACAAAAGTCGATATAAGCACGATGCTTGAAGAAGCGGTCCATTACGTGA AGTTCTTGCAGCTTCAGATTAAGTTGTTGAGCTCGGATGATCTATGGATGT ACGCACCATTGGCTTACAACGGGCCTGGACATGGGGTTCCATCACAACCT TTTGTCTCGGCTTATGTGAggatcctctagagtcgacctgcaggcatgcaagcttT

This fusion is ligated to SacI/KpnI-digested pCambia1300 vector (Hajdukiewicz, P et al 1994 The small pPZP family of Agrobacterium binary vectors for plant transformation Plant Molecular Biology 25, 989-994) or any similar vector.

Plant Transformation and Generation of Homozygous Lines Expressing the Transgene

The EXPpro7:RSL4 transgene is transformed into Arabidopsis thaliana plants. Hygromicin-resistant transformants are selected and grown. Self pollinated lines are selected for plants that are either hemizygous or homozygous for the transgene.

Construction of the gene fusion expressing RSL4 under the control of the GL2 promoter

A fusion of the GL2 promoter and the RSL4 coding sequence is made. This is represented here.

GL2pro (in Bold)::RSL4 (Underlined)

tctaagcggctttggtctgaattttttatatacaaggcctgtctccgtttttgtaaagggaaaacagtaggatccattttagcctct gtaagtaacaatattgggcccctaaaagcccacccattttggggccagcaaaccaaggcaccctcggttccgcacgctcg ctaagacgctaacctatgcatatgttgatatgttttttctcttccttttggtatgaatcttgatttgttttgatactcatgatgtacattc gtattctcttacgtattgtaaaccatcctatttcagatcacgattatatctttacatttacatttttcatttttatttctgtttgaatgttac aatttactagtagagttattcattaaaatactacaactggtatacagaaatgtaatttgagtgataaattatatgaaataattaagt aatatatgtgatatttatggatccaaacaaaaactaattactggttcattttctattttagatgtaagcaaaatgtgtaagattcaag gtatatatatatcccaatatacgtatatatgtggtactcactagctagtagctctctcacaactgtgtcttttggttttcatcagctg atcctctccaactaactatccatcttttgttttgcggttggacttggaggtaccaagaatattagcaacgtacgactcgtatggta tcatttcctttgtacaaaaagtgaatatcaaaatgcattgtattaattatatataagttagtatatggagttagttgtcctcactgtct ttatctggcgcaatctcctatgccatcattccctcttcacacgtacgtgtgcacactcgatgtcacatttgtataaacacgtttgc ttttagcgtgagatcatcaccatattccatttttggtgggtcagttctctttctagatagttatttgtaaggacgtgaattaaaagg gatcgtcgtcacttgttgagataaaagaaaagatatatggtcagtttctgcatcttggaatcaacttaagggttgtcttaattaatt ttgatagaccctactttaaaaattaattagttgctttcattggccctcaataagaaaagccaaaaaagaaagaagactggtctt ggaagtttgccaacacgggtaatagattaatggtgaaaagggcgaatttttttacccaaaaccctaattaagtagaagtattaa tcgagagcaaaaaagagagagagagtcagtagccaaaaggaatgaatggaagaaagaaaaaggaatctctataggcag catatattcaagtaattaattaaagtagatagatagagcaaaaggagaggttaggaggcattaattaattatttaagagcatgt ggtgaatgtaaatgtttatggttgcttccctctctatacattatgtatctacctttcctaactaacaattccctaggccgtacgacg actaacaaagaaaaaaacaaaagaaactgataaagcttttgaattgtagataaatcatctgctacagttataccattatatatct tattaaagacctaagtttccttcactatacgtcttcgtccatttacgtacgtattatacggacggtttaagctactatatctatattgt taacaatgtaactgttgagatatatcttgcaataatatgtcatggtgtatgcatacgataatatgaatcaatgtttgaaatcttgac gtgcccgtgatacaataagatgatcaaaatttcaaattttgtcaaatattaaaacaacatacacatacacatgtgtccaggtgg cattataaaatgtatatatggtggatatagagagagagggagatgcgtatagtgaataggaaagtaagtaataaagagagg gtggaggaattggaaaggggttggaggcaaacccataaagagcattcatttccttttaaggtcgctgaaattaatgagtaac gatcggtcaatgcctctcgctgacctttttctttttttacaacaacaaataaaaataaaataaatttcgacgtctctttccgctgct gaattacatttgttgaattaattttctctgcttacgtacgtcttctaaactttctctatccgaattcttttttaactttctaacttatattca acaactcttctttcctgcctttaccgttagtctaattgttttcctaatactgctacgtacatacccctactatactagtcagtgtatta gattcgattgggattaatccaggaatatagatatcccattagtttttataaaaatattggaagaggacaagtctcaagcaattta gggttccatgtagcgctgcaatatactgttagtaactctctcttacccatatattgtatatgctaattcttatcaaatatatatatatg cttctcccagagtcccagtttcctataatcctgacgcaattatactaatagagccaagtttacataataaagtatatatgattaat agatagggtttcttattaagccatatcttaaattaagatgtgatgatagcgttttgtataagttaccaattgtttgaaagaagagat catcacaataataaatcataagtagtagtatatagtaataaataaatacacaagtcataataagagtaatgagaggataattaa ggagggaagaagaaagcagaaaatgcggttggagaattaggtgctaaaagttagttgagtccatctcagtatctaacggtc aactctctctctctctagagaaaacaattaagaaatctgacatacacatatgtctctctctctctctctctctagtctatacacaca attcaattaaagaagagacagagaagttcgtcttttttgtttttatacccttaaatcaatcatgcaattgtaacccttccttcttattc tcattccttccccccctgtctacagtaatctatagcaacgccattatgtactacttttaacggataatttgctcatgtttcaatatgg cttcattgtatatatgttcaagttcttctcaatcc GGTACCCATGGACGTTTTTGTTGATGGTGAATTGGAGTCTCTCTTGGGGAT GTTCAACTTTGATCAATGTTCATCATCTAAAGAGGAGAGACCGCGAGACG AGTTGCTTGGCCTCTCTAGCCTTTACAATGGTCATCTTCATCAACATCAAC ACCATAACAATGTCTTATCTTCTGATCATCATGCTTTCTTGCTCCCTGATAT GTTCCCATTTGGTGCAATGCCGGGAGGAAATCTTCCGGCCATGCTTGATTC TTGGGATCAAAGTCATCACCTCCAAGAAACGTCTTCTCTTAAGAGGAAAC TACTTGACGTGGAGAATCTATGCAAAACTAACTCTAACTGTGACGTCACA AGACAAGAGCTTGCGAAATCCAAGAAAAAACAGAGGGTAAGCTCGGAAA GCAATACAGTTGACGAGAGCAACACTAATTGGGTAGATGGTCAGAGTTTA AGCAACAGTTCAGATGATGAGAAAGCTTCGGTCACAAGTGTTAAAGGCA AAACTAGAGCCACCAAAGGGACAGCCACTGATCCTCAAAGCCTTTATGCT CGGAAACGAAGAGAGAAGATTAACGAAAGGCTCAAGACACTACAAAACC TTGTGCCAAACGGGACAAAAGTCGATATAAGCACGATGCTTGAAGAAGC GGTCCATTACGTGAAGTTCTTGCAGCTTCAGATTAAGTTGTTGAGCTCGGA TGATCTATGGATGTACGCACCATTGGCTTACAACGGGCCTGGACATGGGG TTCCATCACAACCTTTTGTCTCGGCTTATGTGAGGATCCTCTAGAGTCGAC CTGCAGGCATGCAAGCTTT

This fusion is ligated to digested pCambia1300 vector (Hajdukiewicz, P et al 1994 The small pPZP family of Agrobacterium binary vectors for plant transformation Plant Molecular Biology 25, 989-994), or any similar vector.

Plant Transformation and Generation of Homozygous Lines Expressing the Transgene

The GL2:RSL4 transgene is transformed into Arabidopsis thaliana plants. Hygromicin-resistant transformants are selected and grown. Self-pollinated lines are selected for plants that are either hemizygous or homozygous for the transgene. RSL4 is constitutively expressed in these plants.

REFERENCES

All references cited herein are explicitly incorporated by reference.

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SEQUENCE LISTING SEQ ID NO 1: EXP7pro nucleic acid sequence (Hyung-Taeg Cho et al 2004) GTAGTTAGATGATTACAAAGGGGAAATTTAGGTTAAAAGCGTTTTTTTTTA TTCTGAGTAAAATTTGGGAATAGCTTTAGATTGTGGGGTTACAGATAAAG TAGAGCTATGTGTTAGTAAAAGTCTTTGTGGTAGTGACTTGTGATAATATT TATTGTTACAGGTAAGTGGGAAGAGAGTTGGGATAGTTGGATTGGGGAGC ATTGGATCATTTGTTGCTAAAAGACTTGAATCATTTGGCTGTGTTATCTCT TACAACTCAAGGAGTCAGAAACAGAGTAGTCCATACCGGTATTACTCTGA CATTCTCTCGTTAGCAGAGAACAACGATGTACTTGTCCTCTGCTGCTCTTT GACAGACGAAACGCACCATATTGTGAATAGAGAAGTGATGGAGTTGCTTG GTAAGGATGGGGTTGTGATCAATGTGGGACGAGGAAAGTTGATTGATGA GAAGGAGATGGTCAAGTGTTTGGTTGACGGTGTGATTGGTGGTGCTGGTT TAGATGTGTTTGAGAATGAACCGGCAGTTCCTCAGGAGTTGTTTGGTTTGG ATAATGTAGTGTTGTCTCCTCATTTTGCTGTGGCTACACCAGGGTCTTTGG ACAATGTTGCACAGATTGCTTTAGCTAACTTGAAGGCGTTTTTCTCGAACC GGCCTTTGCTTTCTCCGGTTCAATTGGATTGAGAGAGCGCCCGGTTTGATC AGGTAGCTAAATTAGTTAAGCTATTGTTTATTATAATCAATAATTCAAAAA GAAAGTGTAATGAATATTTGAATGTACCCTGACATTCTCTCCCAAAGAAG AAGAATTAATGACGCATATTATTTAAATAATTCTCCCGCGTTGCACATATG ACTAATTTAGTCGGAACATTACGATTGGCAATATAATCATAATGTTTATGA ATAACCTTTTGGTTCTAATGTTATTGTGAAAATACTGTTAAAACATGATTT CATATATTAGTTTATCTTTGGAAACGTAAATAGTTGACAAACGACAATAT AAAAATAAATGTCTGCTGTTCAATTTAACTAATCATTGAAAATACATAAA CGCACGTATATATAGACATTGGATAGAGTCGGTACACGTATCGTCTATAG AACCTGCTCGCACGTCAACTTATACTATATTCAAAAACCTCACTTAAACA ACAATTGACCTTTTTTCCTAAATTTTATTAGTATTTCTATTGAAAAAATTCA ATGAAATGAAACAAATCCCAATCGGTACGGACAAAAGTCTCCAATAAAA AAGGAATTAAAAAAAAAAAGGATAGTGATCCGCACGTAGCCACCACTAC TGTCGTTGAAAATCCCCTCTATATAAGATTGTCTCAAATTCGATTACTTCA TCAAAAAACAAACCAAAAACAAACCCTAAGAATAAAGAAAAAG AGGCTAGAATGGGTCC SEQ ID NO 2: RSL4 nucleic acid sequence (CDS) (Keke et al 2010) ATGGACGTTTTTGTTGATGGTGAATTGGAGTCTCTCTTGGGGATGTTCAAC TTTGATCAATGTTCATCATCTAAAGAGGAGAGACCGCGAGACGAGTTGCT TGGCCTCTCTAGCCTTTACAATGGTCATCTTCATCAACATCAACACCATAA CAATGTCTTATCTTCTGATCATCATGCTTTCTTGCTCCCTGATATGTTCCCA TTTGGTGCAATGCCGGGAGGAAATCTTCCGGCCATGCTTGATTCTTGGGAT CAAAGTCATCACCTCCAAGAAACGTCTTCTCTTAAGAGGAAACTACTTGA CGTGGAGAATCTATGCAAAACTAACTCTAACTGTGACGTCACAAGACAAG AGCTTGCGAAATCCAAGAAAAAACAGAGGGTAAGCTCGGAAAGCAATAC AGTTGACGAGAGCAACACTAATTGGGTAGATGGTCAGAGTTTAAGCAACA GTTCAGATGATGAGAAAGCTTCGGTCACAAGTGTTAAAGGCAAAACTAGA GCCACCAAAGGGACAGCCACTGATCCTCAAAGCCTTTATGCTCGGAAACG AAGAGAGAAGATTAACGAAAGGCTCAAGACACTACAAAACCTTGTGCCA AACGGGACAAAAGTCGATATAAGCACGATGCTTGAAGAAGCGGTCCATT ACGTGAAGTTCTTGCAGCTTCAGATTAAGTTGTTGAGCTCGGATGATCTAT GGATGTACGCACCATTGGCTTACAACGGGCCTGGACATGGGGTTCCATCA CAACCTTTTGTCTCGGCTTATGTGA SEQ ID NO 3; GL2 nucleic acid sequence of promoter (30033902-30036956) (Szymanski et al., 1998) tctaagcggctttggtctgaattttttatatacaaggcctgtctccgtttttgtaaagggaaaacagtaggatccattttagcctct gtaagtaacaatattgggcccctaaaagcccacccattttggggccagcaaaccaaggcaccctcggttccgcacgctcgctaa gacgctaacctatgcatatgttgatatgttttttctcttccttttggtatgaatcttgatttgttttgatactcatgatgtacattc gtattctcttacgtattgtaaaccatcctatttcagatcacgattatatctttacatttacatttttcatttttatttctgtttgaatgt tacaatttactagtagagttattcattaaaatactacaactggtatacagaaatgtaatttgagtgataaattatatgaaataattaagt aatatatgtgatatttatggatccaaacaaaaactaattactggttcattttctattttagatgtaagcaaaatgtgtaagattcaag gtatatatatatcccaatatacgtatatatgtggtactcactagctagtagctctctcacaactgtgtcttttggttttcatcagctg atcctctccaactaactatccatcttttgttttgcggttggacttggaggtaccaagaatattagcaacgtacgactcgtatggta tcatttcctttgtacaaaaagtgaatatcaaaatgcattgtattaattatatataagttagtatatggagttagttgtcctcactgtct ttatctggcgcaatctcctatgccatcattccctcttcacacgtacgtgtgcacactcgatgtcacatttgtataaacacgtttgc ttttagcgtgagatcatcaccatattccatttttggtgggtcagttctctttctagatagttatttgtaaggacgtgaattaaaagg gatcgtcgtcacttgttgagataaaagaaaagatatatggtcagtttctgcatcttggaatcaacttaagggttgtcttaattaatt ttgatagaccctactttaaaaattaattagttgctttcattggccctcaataagaaaagccaaaaaagaaagaagactggtctt ggaagtttgccaacacgggtaatagattaatggtgaaaagggcgaatttttttacccaaaaccctaattaagtagaagtattaa tcgagagcaaaaaagagagagagagtcagtagccaaaaggaatgaatggaagaaagaaaaaggaatctctataggcag catatattcaagtaattaattaaagtagatagatagagcaaaaggagaggttaggaggcattaattaattatttaagagcatgt ggtgaatgtaaatgtttatggttgcttccctctctatacattatgtatctacctttcctaactaacaattccctaggccgtacgacg actaacaaagaaaaaaacaaaagaaactgataaagcttttgaattgtagataaatcatctgctacagttataccattatatatct tattaaagacctaagtttccttcactatacgtcttcgtccatttacgtacgtattatacggacggtttaagctactatatctatattgt taacaatgtaactgttgagatatatcttgcaataatatgtcatggtgtatgcatacgataatatgaatcaatgtttgaaatcttgac gtgcccgtgatacaataagatgatcaaaatttcaaattttgtcaaatattaaaacaacatacacatacacatgtgtccaggtgg cattataaaatgtatatatggtggatatagagagagagggagatgcgtatagtgaataggaaagtaagtaataaagagagg gtggaggaattggaaaggggttggaggcaaacccataaagagcattcatttccttttaaggtcgctgaaattaatgagtaac gatcggtcaatgcctctcgctgacctttttctttttttacaacaacaaataaaaataaaataaatttcgacgtctctttccgctgct gaattacatttgttgaattaattttctctgcttacgtacgtcttctaaactttctctatccgaattcttttttaactttctaacttatat tcaacaactcttctttcctgcctttaccgttagtctaattgttttcctaatactgctacgtacatacccctactatactagtcagtgtat tagattcgattgggattaatccaggaatatagatatcccattagtttttataaaaatattggaagaggacaagtctcaagcaattta gggttccatgtagcgctgcaatatactgttagtaactctctcttacccatatattgtatatgctaattcttatcaaatatatatatatg cttctcccagagtcccagtttcctataatcctgacgcaattatactaatagagccaagtttacataataaagtatatatgattaat agatagggtttcttattaagccatatcttaaattaagatgtgatgatagcgttttgtataagttaccaattgtttgaaagaagagat catcacaataataaatcataagtagtagtatatagtaataaataaatacacaagtcataataagagtaatgagaggataattaa ggagggaagaagaaagcagaaaatgcggttggagaattaggtgctaaaagttagttgagtccatctcagtatctaacggtc aactctctctctctctagagaaaacaattaagaaatctgacatacacatatgtctctctctctctctctctctagtctatacacaca attcaattaaagaagagacagagaagttcgtcttttttgtttttatacccttaaatcaatcatgcaattgtaacccttccttcttattc tcattccttccccccctgtctacagtaatctatagcaacgccattatgtactacttttaacggataatttgctcatgtttcaatatgg cttcattgtatatatgttcaagttcttctcaatcc SEQ ID NO. 4 RSL4 peptide sequence MENEAFVDGELESLLGMFNFDQCSSNESSFCNAPNETDVFSSDDFFPFGTILQ SNYAAVLDGSNHQTNRNVDSRQDLLKPRKKQKLSSESNLVTEPKTAWRDGQ SLSSYNSSDDEKALGLVSNTSKSLKRKAKANRGIASDPQSLYARKRRERINDR LKTLQSLVPNGTKVDISTMLEDAVHYVKFLQLQIKLLSSEDLWMYAPLAHNG LNMGLHHNLLSRLI RHD6 amino acid sequence (At1g66470; NP_176820.1 GI: 15219658 SEQ ID NO: 5) MALVNDHPNETNYLSKQNSSSSEDLSSPGLDQPDAAYAGGGGGGGSASSSST MNSDHQQHQGFVFYPSGEDHHNSLMDFNGSSFLNFDHHESFPPPAISCGGSS GGGGFSFLEGNNMSYGFTNWNHQHHMDIISPRSTETPQGQKDWLYSDSTVV TTGSRNESLSPKSAGNKRSHTGESTQPSKKLSSGVTGKTKPKPTTSPKDPQSL AAKNRRERISERLKILQELVPNGTKVDLVTMLEKAISYVKFLQVQVKVLATD EFWPAQGGKAPDISQVKDAIDAILSSSQRDRNSNLITN RHD6 nucleotide sequence (NM_105318.2 GI: 30697352 SEQ ID NO: 6) atggcactcgttaatgaccatcccaacgagaccaattacttgtcaaaacaaaattcctcc tcttccgaagatctctcctcgccgggactggatcagccagatgcagcttatgccggtgga ggaggaggaggaggctcggcttcgagcagtagcacgatgaattcagatcatcaacaacat caggggtttgtattttacccatccggtgaagatcatcacaactctttgatggatttcaac ggatcatcatttcttaactttgatcatcacgagagctttcctcctccagccataagctgt ggtggtagtagcggtgggggcggcttctccttcttggagggcaacaacatgagctacggc ttcacaaactggaatcatcaacatcatatggatattattagccctagatccaccgaaact ccccaaggccagaaagactggttatattctgattcaactgttgtaaccactggttctaga aacgagtctctttcgcctaaatccgctggaaacaaacgttctcacacgggagagagcact caaccgtcgaagaaactgagtagcggtgtgaccggaaagaccaagcctaagccaacaact tcacctaaagatccacaaagcctagcagccaagaatcgaagagaaaggataagtgaacgt ctcaagatattgcaagaacttgttcccaatggcaccaaggttgatttggtgacaatgctt gaaaaggctattagttatgtcaagttccttcaagtacaagttaaggtattagcgaccgat gagttttggccggctcaaggaggaaaagctcctgacatttctcaagttaaagacgccatt gatgccattctctcctcatcacaacgagacaggaattcgaatctgatcaccaattaa RSL1 amino acid sequence (At5g37800 SEQ ID NO: 7) MSLINEHCNERNYISTPNSSEDLSSPQNCGLDEGASASSSSTINSDHQNN QGFVFYPSGETIEDHNSLMDFNASSFFTFDNHRSLISPVTNGGAFPVVDG NMSYSYDGWSHHQVDSISPRVIKTPNSFETTSSFGLTSNSMSKPATNHGN GDWLYSGSTIVNIGSRHESTSPKLAGNKRPFTGENTQLSKKPSSGTNGKI KPKATTSPKDPQSLAAKNRRERISERLKVLQELVPNGTKVDLVTMLEKAI GYVKFLQVQV KVLAADEFWP AQGGKAPDIS QVKEAIDAIL SSSQRDSNSTRETSIAE RSL1 nucleotide sequence (SEQ ID NO: 8) atgtcactcattaacgaacattgcaatgagcgtaattacatctcaaccccaaattcttca gaagatctctcttcaccacagaattgcggattagacgaaggagcttcagcttcaagcagt agcaccataaattctgatcatcaaaataatcaagggtttgtgttttacccttccggggaa accattgaagatcataattctttgatggatttcaatgcttcatcattcttcacctttgat aatcaccgaagccttatctctcccgtgaccaacggtggtgccttcccggtcgtggacggg aacatgagttacagctatgatggctggagtcatcatcaagtggatagtattagccctaga gtcatcaaaactccaaatagctttgaaacaacgagcagttttggattgacttcaaactcc atgagtaaaccggccacaaaccatggaaatggagactggttatactctggttcaactatt gtaaacatcggttcaaggcacgagtccacgtcccctaaactggctggcaataaacggcct ttcacgggagagaacacacaactttcaaagaagccgagtagcggtacgaatggaaagatc aagcctaaggcaacaacttcacctaaagatccacaaagcctagcagccaagaaccgaaga gaaaggataagcgaacgcctcaaggtattgcaagaacttgtaccgaatggtaccaaggtg gatttggtaactatgcttgagaaagcaattggctatgtaaagtttcttcaagtacaagtt aaggtacttgcagccgatgagttttggccggcacaaggagggaaagctccggacatttct caagttaaagaagctattgacgcaatcctctcatcatcacaacgagatagtaactcaact agagaaacaagtatagcagaataa RSL2 amino acid sequence (At4g33880; SEQ ID NO: 9) MEAMGEWSNN LGGMYTYATE EADFMNQLLA SYDHPGTGSS SGAAASGDHQ GLYWNLGSHHNHLSLVSEAG SFCFSQESSS YSAGNSGYYT VVPPTVEENQ NETMDFGMED VTINTNSYLVGEETSECDVE KYSSGKTLMP LETVVENHDD EESLLQSEIS VTTTKSLTGS KKRSRATSTDKNKRARVNKR AQKNVEMSGD NNEGEEEEGE TKLKKRKNGA MMSRQNSSTT FCTEEESNCADQDGGGEDSS SKEDDPSKAL NLNGKTRASR GAATDPQSLY ARKRRERINE RLRILQNLVP NGTKVDISTM LEEAVHYVKF LQLQIKLLSS DDLWMYAPIA FNGMDIGLSS PR RSL2 nucleotide sequence (SEQ ID NO: 10) atggaagccatgggagaatggagcaacaacctcggaggaatgtacacttatgcaaccgag gaagccgatttcatgaaccagcttctcgcctcttatgatcatcctggcaccggctcatcc tccggcgcagcagccagtggtgaccaccaaggcttgtattggaaccttggttctcatcac aaccaccttagcctcgtgtctgaagccggtagcttctgtttctctcaagagagcagcagc tacagcgctgggaacagcggatattacaccgttgttccacccacggttgaagagaaccaa aatgagacaatggactttgggatggaagatgtgaccatcaatacaaactcataccttgtt ggtgaggagacaagtgagtgtgacgttgagaaatactcttctggaaagactcttatgcct ttggaaaccgtagtggagaaccacgatgacgaggaaagcttgttgcaatctgagatctct gtgactactacaaaatctctcaccggctccaaaaagagatcccgtgccacatctactgat aaaaacaagagagcaagagtgaataagagggcccagaagaacgtagagatgagtggggat aacaatgaaggagaagaggaagaaggagagacgaagttgaagaaaagaaagaatggggca atgatgagtagacagaactcaagcaccactttctgtacggaggaagaatcaaactgcgct gatcaagacggtggaggagaagactcatcctctaaggaagatgatccctcaaaggccctc aacctcaatggtaaaacaagagccagtcgtggtgcagccaccgatcctcaaagcctctat gcaaggaaaagaagagaaaggattaacgagagactaaggattttacaaaatctcgtcccc aatggaacaaaggtcgatattagtacaatgcttgaggaagcagttcattacgtcaaattt ttgcagctccaaattaagttattgagctctgatgatctatggatgtatgcgccgattgct ttcaatgggatggacattggtctcagctcaccgagatga RSL3 amino acid sequence (At2g14760; SEQ ID NO: 11) MEAMGEWSTGLGGIYTEEADFMNQLLASYEQPCGGSSSETTATLTAYHHQ GSQWNGGFCFSQESSSYSGYCAAMPRQEEDNNGMEDATINTNLYLVGEET SECDATEYSGKSLLPLETVAENHDHSMLQPENSLTTTTDEKMFNQCESSK KRTRATTTDKNKRANKARRSQKCVEMSGENENSGEEEYTEKAAGKRKTKP LKPQKTCCSDDESNGGDTFLSKEDGEDSKALNLNGKTRASRGAATDPQSL YARVDISTML EEAVQYVKFL QLQIKRLLAI GTNHRNRSIP LWTARNRQIS KAHSRKRLRLRAVAKIIWSDEMTRFLLELITLEKQAGNYRGKS LIEKGKE NVLVKFKKRFPITLNWNKVNRLDTLKKQYEIYPAKLRSH PLRFIPLLDV VFRDETVVVE ESWQPRRGVHRRAPVLDLSDSECPNNNGDEREDLMQNRERDHMRPPTPDW MSQTPMENSPTSANSDPPFASQERSSTHTQVKNVSRNRKRKQNPADSTLD RIAATMKKI RSL3 nucleotide sequence (SEQ ID NO: 12) atggaagccatgggagaatggagcaccggcctaggcggaatatatacagaggaagctgac tttatgaatcagctccttgcctcctatgagcaaccttgtggcggttcatcttcagagaca accgccacactcacggcctaccaccaccagggttctcaatggaatggtggcttttgcttc tctcaggagagcagtagttatagtggttactgcgcggcgatgccacggcaagaagaagat aacaatgggatggaggacgcgacaatcaacacgaacttgtaccttgttggtgaagagaca agtgaatgtgatgcgacggaatactccggtaaaagcctcttgcctttggagactgtcgca gaaaaccacgaccatagtatgctacagcctgagaactccttgaccacgaccactgatgag aaaatgttcaaccaatgtgagagttcaaagaagaggacgcgtgccacaacaactgataag aacaagagagccaacaaggcacgaaggagccagaaatgcgtagagatgagtggcgaaaat gaaaatagcggcgaagaagaatatacggagaaggctgcggggaagagaaagaccaaacca cttaagccgcaaaagacttgttgttcggatgacgaatcaaacggtggagacactttcttg tccaaagaagatggcgaggactctaaggctctcaacctcaacggcaagactagggccagc cgcggcgcggccacagatcctcaaagcctttacgcaaggaaaagaagagagaggataaac gagaggctaaggattttgcaacatctcgtccctaatggaacaaaggttgatattagcacg atgttggaagaagcagtacaatacgtcaaatttctacagctccaaattaagttattgagc tctgatgatctatggatgtatgcgcctattgcttacaacggaatggacattggccttgac ctaaaactcaatgcactgaccagatga RSL5 amino acid sequence (At5g43175; SEQ ID NO: 13) MENEAFVDGELESLLGMFNFDQCSSNESSFCNAPNETDVFSSDDFFPFGTILQ SNYAAVLDGSNHQTNRNVDSRQDLLKPRKKQKLSSESNLVTEPKTAWRDGQ SLSSYNSSDDEKALGLVSNTSKSLKRKAKANRGIASDPQSLYARKRRERINDR LKTLQSLVPNGTKVDISTMLEDAVHYVKFLQLQIKLLSSEDLWMYAPLAHNG LNMGLHHNLLSRLI RSL5 nucleotide sequence (SEQ ID NO: 14) atggagaatgaagcttttgtagatggtgaattggagtctcttttggggatgttcaacttt gatcaatgttcatctaacgaatcgagcttttgcaatgctccaaatgagactgatgttttc tcttctgatgatttcttcccatttggtacaattctgcaaagtaactatgcggccgttctt gatggttccaaccaccaaacgaaccgaaatgtcgactcaagacaagatctgttgaaacca aggaagaagcaaaagttaagctcggaaagcaatttggttaccgagcctaagactgcttgg agagatggtcaaagcctaagcagttataatagttcagatgatgaaaaggctttaggttta gtgtctaatacatcaaaaagcctaaaacgcaaagcgaaagccaacagagggatagcttcc gatcctcagagcctatacgctaggaaacgaagagaaaggataaacgataggctaaagaca ttgcagagcctagttcctaatgggacaaaggtcgatataagcacaatgctggaagatgct gtccattacgtgaagttcctgcagcttcaaatcaagctcttgagttcagaagatctatgg atgtatgcacctcttgctcacaatggtctgaatatgggactacatcacaatcttttgtct cggcttatttaa AtRHD6 bHLH amino acid sequence (SEQ ID NO: 15) TSPKDPQSLAAKNRRERISERLKILQELVPNGTKVDLVTMLEKAISYVKFLQV QVKVLATDEFWPAQ AtRLD1 bHLH amino acid sequence (SEQ ID NO: 16) TSPKDPQSLAAKNRRERISERLKVLQELVPNGTKVDLVTMLEKAIGYVKFLQ VQVKVLAADEFWPAQ PpRSL1 bHLH amino acid sequence (SEQ ID NO: 17) GSANDPQSIAARVRRERISERLKVLQALIPNGDKVDMVTMLEKAISYVQCLEF QIKMLKNDSLWPKA PpRSL2 bHLH amino acid sequence (SEQ ID NO: 18) GSANDPQSIAARVRRERISERLKVLQALIPNGDKVDMVTMLEKAITYVQCLE LQIKMLKNDSIWPKA PpRSL5 bHLH amino acid sequence (SEQ ID NO: 19) GSATDPQSVYARHRREKINERLKSLQNLVPNGAKVDIVTMLDEAIHYVKFLQ NQVELLKSDELWIYA PpRSL6 bHLH amino acid sequence (SEQ ID NO: 20) GSATDPQSVYARHRREKINERLKNLQNLVPNGAKVDIVTMLDEAIHYVKFLQ TQVELLKSDEFWMFA PpRSL3 bHLH amino acid sequence (SEQ ID NO: 21) GSATDPQSVYARHRREKINERLKTLQHLVPNGAKVDIVTMLDEAIHYVQFLQ LQVTLLKSDEYWMYA PpRSL4 bHLH amino acid sequence (SEQ ID NO: 22) GSATDPQSVHARARREKIAERLRKLQHLIPNGGKVDIVTMLDEAVHYVQFLK RQVTLLKSDEYWMYA PpRSL7 bHLH amino acid sequence (SEQ ID NO: 23) GSATDPQSVYARHRREKINERLKTLQRLVPNGEQVDIVTMLEEAIHFVKFLEF QLELLRSDDRWMFA At4g33880 bHLH amino acid sequence (SEQ ID NO: 24) GAATDPQSLYARKRRERINERLRILQNLVPNGTKVDISTMLEEAVHYVKFLQ LQIKLLSSDDLWMYA At2g14760 bHLH amino acid sequence (SEQ ID NO: 25) GAATDPQSLYARKRRERINERLRILQHLVPNGTKVDISTMLEEAVQYVKFLQ LQIKLLSSDDLWMYA At1g27740 bHLH amino acid sequence (SEQ ID NO: 26) GTATDPQSLYARKRREKINERLKTLQNLVPNGTKVDISTMLEEAVHYVKFLQ LQIKLLSSDDLWMYA At5g43175 bHLH amino acid sequence (SEQ ID NO: 27) GIASDPQSLYARKRRERINDRLKTLQSLVPNGTKVDISTMLEDAVHYVKFLQ LQIKLLSSEDLWMYA Physcomitrella RHD SIX LIKE 1 (PpRSL1) amino acid sequence (SEQ ID NO: 28; AB084930.1 GI: 140084327) MAGPAGALWSTCDPQPIQQAEIFSGPDNQAGLMSFHVDTPFHWGSEPWALH SRSDDIALMSPSLVHDISPYDSVLHLSGVSGDVQDLVCGNPKFRQSGQWGQS EFSYSVQDNMQDLLTNQFIPYNTSSLGLNHLSPNFTDLDCAPVYNDTKAFGT VTHNRAVPSTNTQSAQHGSSSMVSSNRPITSTASPTTQYGGPRTPSQTTQYGG SSMVTNSMEMFASAAPQGIMTTSGLSGGCNSDLMHLPKRQHAHSLPPTTGR DLTASEVVSGNSISNISGVGSFNSSQKSSASVMMSPLAASSHMHKAAAVSEEL KMASFNPGPFVPTQKKQQHEQQDTMTSNRIWADKNNLGKISSSPIPIMGFEQS QQQSMSNSSPVTSLGFEQRQKMSMGSSPSITIIGFEQRQKQPMSSSSPISNMVF EPRQKQPMSSSSPISNIVFEQRQLPTVGSSPPISISGFEPKKQPSLSNSPPLSNLGF EQRLQPMSNASPISNLPFEQQRQQATMSNTRSAEPDSVESTTKWPLRMDGAI GGCAGLPSSQKAPVIMQPETGTMKCPIPRTMPSNAKACPAVQNANSVNKRPL TVDDKDQTGSMNKKSMQKFLGPQGCSRLESISALAHQKVSQSTTSGRALGP ALNTNLKPRARQGSANDPQSIAARVRRERISERLKVLQALIPNGDKVDMVTM LEKAISYVQCLEFQIKMLKNDSLWPKALGPLPNTLQELLELAGPEFAGIDGKN TEESSEKPKKSALEVIELDGNQPSAD* Physcomitrella RHD SIX LIKE 1 (PpRSL1) nucleotide sequence (SEQ ID NO: 29; EF156393.1 GI: 140084326) atggcaggtccagcaggagctttatggagtacttgtgatccacagcctattcaacaggcagagatatttagtggtcctgaca accaagctggtttgatgtcttttcatgtggataccccgttccattggggatctgaaccatgggctctccactctcggtcagatg acatcgccttgatgtccccctcgcttgttcacgacatatcaccttatgattctgtcttgcatctttccggagtgtctggggatgtg caagatttagtttgcgggaatcccaaatttcgccaaagtgggcaatgggggcagagcgagttttcatactctgttcaggaca acatgcaagatctcctaaccaaccagttcataccgtacaacacatcttcattgggtttaaatcatctctccccgaatttcaccga cttggattgcgcaccggtatacaatgataccaaggcttttggcactgttacacacaacagggcagtcccgagcactaatacc cagagtgctcagcacgggagttcgtctatggtttcaagtaacaggccaatcactagcacagcttctcctactactcagtatgg aggtccgaggactccatcccaaaccacccagtacgggggttcatctatggttaccaactcgatggaaatgtttgcttcagct gcacctcagggtattatgactacatctggcttgagtggcggttgcaactcagacttgatgcatctgccgaagcgccagcatg ctcactctcttcctcctaccactggcagagatttaactgcatctgaagtggtatctggaaattcgatatcaaacatttccggggt tggatcttttaacagcagccagaaaagcagtgcatccgtgatgatgtctcctttagctgcttcttctcacatgcacaaggctgc tgctgtatctgaagaacttaagatggcaagtttcaaccctggtccattcgtacctacgcagaaaaagcagcaacatgagcag caggatacgatgacctctaatcgtatatgggcggataagaacaacttgggaaaaattagttcatcgcccattccgatcatgg ggtttgagcagagtcaacagcaatccatgagcaattcctcccctgttaccagtttggggtttgagcaaaggcaaaaaatgtc catgggtagctctccctccatcacgatcattggatttgagcaaagacagaagcaacctatgagtagttcttcccccatttcaaa catggtttttgaaccaagacaaaaacagccaatgagtagctcttctcctatctctaatattgtctttgagcaaagacaactccca actgtgggtagctctcctccgatttcaatctcaggatttgagccaaagaaacaaccatctttgagcaattctcctcccctctcta atctgggttttgagcaaaggctacaacccatgagtaatgcatctcctatttccaacttaccctttgagcaacaaagacaacaa gcaaccatgagtaacaccagatctgcagaacccgattctgtcgagtctaccacgaagtggcccttgcggatggatggtgc cataggtggatgtgctggcttaccaagcagtcagaaagctcctgttatcatgcagcctgagactgggactatgaagtgtcct attccgaggaccatgcccagcaatgctaaggcttgcccagctgtgcagaatgctaattccgtaaacaagcgccctcttacg gttgatgacaaggaccaaactggatcgatgaataagaagtcgatgcaaaagtttttgggacctcaaggttgtagcagacttg aaagtatcagtgctttagctcaccaaaaagtgagtcaaagtacaacaagcggtcgtgctctagggcctgctttgaacaccaa tctcaagcctcgtgcacgccaagggagtgccaatgatccgcagagcattgctgctagggtgcgaagagaaagaataagt gagcggctcaaagttttgcaagccttgatacctaacggtgataaagtggatatggtcaccatgctggagaaggctatcagct acgtgcagtgtttggaatttcagattaagatgttaaaaaatgactctttgtggcctaaggcgcttggccctctaccgaacacttt gcaagagcttctcgaacttgctgggccagagtttgccggcatagatggcaagaatactgaggagtcgtcagagaaaccga agaaatctgctcttgaagtaattgagttggacggcaatcagccttctgctgactaa Physcomitrella RHD SIX LIKE 2 (PpRSL2) amino acid sequence (SEQ ID NO: 30 AB084931.1 GI: 140084334) MNKKPMQKALGPQGCSRLESISALAHQKVSQSASGRALGPALNTNLKPRAR QGSANDPQSIAARVRRERISERLKVLQALIPNGDKVDMVTMLEKAITYVQCL ELQIKMLKNDSIWPKALGPLPNTLQELLELAGPEFSGTESKNVEEPPAKPKKS APDVIEFDGNQPSADKE* Physcomitrella RHD SIX LIKE 2 (PpRSL2) nucleotide sequence (SEQ ID NO: 31; EF156394.1 GI: 140084333) atgaataagaagcctatgcaaaaagctttgggacctcaaggatgcagcaggctagaaagcatcagtgctttagctcatcaa aaagtgagtcagagtgcaagtggtcgtgcactagggcctgctctgaacaccaacctcaagcctcgtgctcgtcaagggag tgccaatgacccacagagcattgccgctagggttcgaagagaaaggataagtgagcggctgaaagttttgcaagccttgat acctaatggtgataaggtagatatggtgaccatgctggagaaggctatcacctacgtgcagtgtctggaactccagattaag atgttaaagaatgattctatctggcccaaggcgcttggacctctaccaaacactcttcaagagcttctggagcttgctggacc agaattttctggaacggaaagcaagaatgtagaggagcccccagcgaagccaaagaaatcagctcctgacgttattgagtt cgacggcaatcaaccttctgccgacaaagagtag Physcomitrella RHD SIX LIKE 3 (PpRSL3) amino acid sequence (SEQ ID NO: 32; AB084932.1 GI: 140084346) GSATDPQSVYARHRREKINERLKTLQHLVPNGAKVDIVTMLDEAIHYVQFLQ LQVTLLKSDEYWMYA Physcomitrella RHD SIX LIKE 3 (PpRSL3) nucleotide sequence (SEQ ID NO: 33; EF156395.1 GI: 140084345) ggttcagcgactgatccgcagagtgtatatgccaggcatagaagggagaagatcaacgagcgcttgaagacattacagc acttggtaccaaatggagctaaggtagacatcgtgaccatgcttgacgaagccattcactacgtccaatttctgcagctccaa gtgacgctgttgaagtcggatgaatattggatgtacgcc Physcomitrella RHD SIX LIKE 4 (PpRSL4) amino acid sequence (SEQ ID NO: 34; AB084933.1 GI:140084359) MTDLISILESSGSSREEMCPVAVPSSVASSCERLIWEGWTAQPSPVEESTTSKL LPKLLPELETSSYSALTLQQPDALSSILSVLHPFSHYSSASLELARNPDWSLKSS NPLRESSSEAGIRTSSFEGLYSGQHTTKKIHLGVIPYHLSEDQRQCAVSPPENE CRLLSANSSGSLHWWHSIGPESPSSTLAFHNIGIQHSTFEKCEPRGQSHSSWPA ASGTSPTVQYFHAHSADNEGVEVVKQDDSQISKALATYQPHGDHSLVLNSD RIASTTSHSEDPCGPKPGRRPAASYDTEMILSPSESFLTTPNMLSTLECVISGAS NISDQYMNFVREPQEQRLSSISDLSLIPDSHADPHSIGFISGTFRTDSHGTGIRK NRIFLSDEESDFLPKKRSKYTVRGDFQMDRFDAVWGNTGLRGSSCPGNSVSQ MMAIYEFGPALNRNGRPRVQRGSATDPQSVHARARREKIAERLRKLQHLIPN GGKVDIVTMLDEAVHYVQFLKRQVTLLKSDEYWMYATPTSYRSKFDDCSLV PGENN* Physcomitrella RHD SIX LIKE 4 (PpRSL4) nucleotide sequence (SEQ ID NO: 35; EF156396.1 GI: 140084358) ATGACCGATCTGATTTCGATCTTGGAGTCATCAGGGTCATCACGAGAGGA GATGTGCCCTGTTGCTGTGCCAAGCTCCGTGGCTTCTTCTTGTGAAAGGTT GATATGGGAGGGGTGGACTGCACAACCATCTCCTGTCGAAGAAAGCACC ACCAGCAAGTTACTTCCAAAGCTACTTCCAGAGCTCGAGACATCATCCTA CTCTGCACTCACCCTTCAGCAACCTGATGCGCTCTCCAGCATACTTTCAGT CCTCCACCCTTTTTCTCATTACAGTTCGGCCAGTTTAGAACTCGCTCGCAA TCCTGACTGGAGCTTGAAATCTTCAAATCCTCTGCGGGAAAGCAGCTCGG AGGCTGGCATCCGAACCTCATCTTTCGAAGGCTTGTACTCTGGTCAGCAC ACCACCAAAAAGATTCATTTGGGGGTCATACCCTACCACTTGTCCGAAGA TCAGCGCCAGTGCGCTGTCAGTCCTCCGGAAAATGAGTGCCGCCTACTGT CTGCAAATTCCTCTGGATCCCTTCACTGGTGGCATTCCATAGGCCCCGAGT CTCCTTCCTCTACTCTTGCATTCCATAATATTGGGATCCAACACTCTACCTT CGAAAAGTGTGAGCCTAGGGGCCAGTCGCACTCATCATGGCCAGCGGCC AGCGGCACGTCGCCAACAGTTCAATACTTTCATGCCCATTCTGCAGATAA TGAAGGTGTCGAGGTCGTCAAGCAAGATGACTCGCAGATATCCAAGGCTC TGGCGACCTATCAACCCCACGGCGACCATAGTCTCGTGCTAAATTCAGAC CGCATTGCAAGCACAACCAGCCACTCAGAAGATCCTTGCGGCCCTAAACC TGGACGCAGACCAGCTGCATCATACGACACCGAGATGATTCTTAGCCCAA GTGAGAGTTTCTTGACAACTCCCAATATGTTATCAACGTTGGAGTGCGTA ATATCCGGTGCAAGTAACATATCTGATCAGTATATGAACTTCGTCAGAGA ACCGCAGGAGCAAAGGCTGTCCTCTATCTCCGATCTGTCCCTTATTCCTGA CAGCCACGCGGATCCGCACAGTATCGGATTTATCTCTGGGACCTTTAGAA CAGACTCCCACGGAACTGGAATAAGAAAGAACCGCATCTTTCTCAGTGAT GAGGAATCCGACTTCTTGCCTAAGAAGCGATCCAAGTACACGGTCCGCGG CGATTTTCAGATGGATCGCTTCGACGCAGTTTGGGGGAATACCGGTCTTC GGGGATCTAGCTGTCCTGGAAATTCAGTATCCCAGATGATGGCGATTTAC GAATTCGGACCCGCACTGAACAGGAACGGCAGGCCGCGAGTACAACGTG GTTCGGCGACTGATCCGCAGAGTGTACACGCCAGGGCGCGGAGGGAGAA AATCGCCGAGCGCTTGAGAAAGTTGCAGCACCTCATTCCAAACGGCGGGA AGGTGGACATCGTAACCATGCTCGACGAAGCCGTTCACTATGTTCAGTTTT TGAAGCGACAAGTTACGCTTCTGAAATCCGACGAGTATTGGATGTACGCC ACGCCGACCTCGTACCGGAGCAAATTCGACGACTGCAGTCTGGTTCCCGG CGAGAACAACTGA Physcomitrella RHD SIX LIKE 5 (PpRSL5) amino acid sequence (SEQ ID NO: 36: AB084934.1 GI: 140084368) MVQLYMSSVEEQRETMVQPYVSSMDSGSTSGRQTPSCVVQQGSNTFETSNL WEEWTQASNGDDTVSTSNFLPEISSFTSSRLSFQQSDSLTTWMSGFPPLSQTA LSPDLSHSSDPVDHPPAFMQEGLGPGDSILDYSPALTEMYPKSSSKHNSSDCL PYPAASAPDKKMTDHELGSAISLAYDRGTVSRQLLRALGPLSPSSPLALQNGL QNPLGDPWDASPSAMPWPMATTGHAYGPGATRTSIPDHLANAINHLEGIAPS SASHASKPRHTDIFIAPNGTFDSTPGGWTPQYYDGSVTTDESVKAMKLIASLR EAGHAEATIGFCTESKPSFLRGGDRTTSPVDSFFGKCVGAKTSIKQACSGKHP LELEEIVDSENSELNPTQLKRSKLFENHPNALWSDQSMNGRELRSYSHLVGSS LTASQPMDIIAIGPALNTDGKPRAKRGSATDPQSVYARHRREKINERLKSLQN LVPNGAKVDIVTMLDEAIHYVKFLQNQVELLKSDELWIYATPNKYNGMDISD LSDMYLQELESRA* Physcomitrella RHD SIX LIKE 5 (PpRSL5) nucleotide sequence (SEQ ID NO: 37; EF156397.1 GI: 140084367) ATGGTGCAGTTATACATGTCCTCAGTTGAAGAGCAGCGGGAAACAATGGT ACAGCCATACGTCTCAAGCATGGACTCAGGCTCAACGTCGGGGCGCCAGA CGCCATCTTGCGTCGTTCAGCAGGGAAGTAACACATTTGAGACTTCGAAT CTGTGGGAGGAATGGACGCAAGCATCGAACGGCGACGATACAGTCTCCA CCAGCAATTTCCTCCCCGAAATCAGTTCCTTCACGTCGAGTCGTCTCTCCT TCCAGCAAAGCGACTCTCTCACCACTTGGATGTCAGGGTTCCCTCCCCTCT CCCAAACTGCCTTGAGCCCGGATCTTAGTCACTCCTCCGACCCCGTGGATC ATCCCCCAGCATTCATGCAGGAGGGTTTAGGCCCCGGTGATTCTATTCTGG ACTATTCCCCCGCTCTCACAGAGATGTACCCGAAAAGTAGCTCCAAACAT AATTCCTCGGATTGTTTACCTTACCCTGCGGCCAGTGCACCAGACAAAAA AATGACTGATCACGAACTAGGTTCGGCTATTTCCCTCGCGTATGATAGAG GCACCGTTTCCCGCCAGCTTCTTCGAGCCTTGGGCCCATTGTCGCCTTCAT CGCCTCTAGCATTGCAGAATGGGCTGCAAAACCCGCTTGGGGACCCCTGG GATGCTTCTCCATCTGCAATGCCGTGGCCAATGGCAACAACCGGTCATGC TTATGGACCAGGCGCCACCAGGACTTCTATTCCAGATCACTTAGCAAATG CAATTAATCACCTGGAGGGCATTGCACCGTCCAGTGCCAGTCATGCATCG AAACCTCGTCACACTGATATTTTCATTGCACCCAATGGCACGTTCGATTCG ACGCCGGGAGGTTGGACACCGCAGTATTACGATGGGTCCGTGACGACAG ATGAGTCTGTGAAGGCGATGAAGCTGATTGCGTCCCTACGTGAAGCAGGC CACGCAGAGGCTACAATTGGATTCTGTACAGAGAGCAAGCCTAGTTTTCT CAGGGGTGGGGACAGAACAACCTCGCCAGTGGACAGCTTCTTCGGCAAA TGTGTAGGGGCCAAAACGAGTATAAAGCAAGCCTGTTCTGGGAAACACCC TCTTGAACTTGAGGAGATCGTTGATAGTGAAAACAGTGAATTAAATCCCA CCCAGCTCAAACGCTCTAAACTTTTTGAGAATCATCCGAATGCCTTGTGGA GCGATCAGAGTATGAATGGAAGAGAACTGAGATCGTACTCTCATTTGGTT GGCAGCAGTCTTACTGCATCGCAGCCCATGGACATAATTGCAATTGGCCC AGCGCTCAACACTGATGGCAAACCACGAGCAAAGCGGGGTTCAGCAACC GATCCTCAGAGTGTTTACGCTAGACATAGGAGAGAAAAAATCAACGAAC GATTGAAGAGTTTACAAAACCTAGTACCTAATGGAGCCAAGGTTGACATA GTAACCATGCTGGACGAAGCTATACATTACGTCAAATTTTTACAAAATCA AGTTGAGCTGCTGAAGTCCGACGAGTTGTGGATTTACGCAACACCAAATA AGTACAACGGCATGGACATTTCCGACCTCTCTGACATGTATTTGCAGGAG CTGGAGTCACGTGCGTGA Physcomitrella RHD SIX LIKE 6 (PpRSL6) amino acid sequence (SEQ ID NO: 38; AB084935.1 GI: 140084376) MVRFNYMYPVQEQLEAMTDQHTPSMDSVSSAGEKTSSCIVQQGGNASETSN LWEEWTQGSNGDDSVSTSNFLPELNSSTSSRLAFHQSDILSTWISGYHPLSQSS LSSEFSHTSDRENHPPAFMQEGLIPSGLILDSDPALTDIYTRSSSSDSLPYPTARI MDKALTDHELESAVPLAYEKGCVPPQVLRNLGPLSPSSPLAFQNGLLNPLRD PWDSCPSALPWSNVTTASQTYGQVTTRTFIPDHSASAIDKLEAVATITAGYGA SKPQHTDVFIEPNGTFQSTPAGWAPQFYDGSEATGLLVKPMRAIASLGEAGC GEATSEFCTKTKPGLLKGGDTITSPVGSLLGDCKKAESSMKQVWPGKHRLEL VELVDGEDTKSSPTQLKRPKHSTDYANVLLSDHILKGAELRSYFHSGDVGLN ASQAMDIIVIGPALNTNGKPRAKRGSATDPQSVYARHRREKINERLKNLQNL VPNGAKVDIVTMLDEAIHYVKFLQTQVELLKSDEFWMFANPHNYNGIDISDP SSMHSPELESNI* Physcomitrella RHD SIX LIKE 6 (PpRSL6) nucleotide sequence (SEQ ID NO: 39: EF156398.1 GI: 140084375) ATGGTGCGGTTTAACTACATGTACCCGGTTCAAGAGCAGCTGGAAGCCAT GACGGACCAACACACCCCAAGCATGGATTCGGTCTCGTCGGCCGGAGAG AAGACATCCTCTTGCATCGTCCAGCAGGGAGGAAATGCATCCGAAACTTC AAACTTGTGGGAAGAATGGACACAAGGGTCGAACGGCGACGATTCTGTCT CTACCAGCAACTTCCTCCCCGAACTGAATTCCTCCACCTCCAGTCGTCTCG CATTCCACCAAAGCGACATTCTTTCCACTTGGATCTCAGGCTACCACCCAC TCTCGCAAAGCAGCCTGAGTTCCGAATTCAGCCACACCTCCGACCGCGAG AATCACCCCCCAGCATTCATGCAAGAGGGTTTAATCCCCAGTGGTTTAATT CTTGACTCTGATCCTGCTCTCACAGATATTTATACGAGAAGCAGCTCCTCG GACTCTTTGCCATACCCCACGGCTAGGATCATGGACAAAGCATTGACCGA TCACGAGCTTGAGTCTGCTGTCCCACTTGCATATGAAAAAGGCTGCGTTCC TCCCCAGGTTCTGCGTAACCTAGGGCCATTGTCACCTTCTTCGCCTCTGGC ATTCCAGAATGGACTGCTAAACCCCCTCAGGGACCCTTGGGATTCGTGTC CATCTGCATTGCCATGGTCAAATGTGACCACAGCCAGCCAGACTTACGGT CAAGTGACAACCAGGACTTTCATTCCAGATCACTCTGCAAGTGCAATCGA CAAGTTGGAGGCCGTCGCAACGATCACTGCCGGATACGGCGCGTCGAAA CCACAACATACTGACGTCTTCATAGAACCCAACGGGACGTTTCAGTCGAC TCCGGCAGGGTGGGCACCGCAGTTTTACGATGGATCCGAGGCGACGGGCC TGTTGGTCAAGCCAATGAGGGCCATCGCATCTCTGGGTGAAGCCGGCTGT GGGGAGGCCACTAGTGAATTCTGCACAAAGACCAAGCCAGGACTTCTCA AAGGTGGGGACACAATAACCTCGCCGGTGGGTAGCCTGTTGGGCGATTGC AAAAAAGCTGAGTCAAGTATGAAGCAAGTTTGGCCTGGAAAACACCGTCT TGAACTCGTGGAACTAGTCGATGGTGAAGACACCAAATCAAGTCCCACCC AGCTCAAACGGCCGAAACATTCTACGGATTATGCGAATGTCCTGTTGAGC GATCATATTCTGAAAGGAGCGGAGCTGCGGTCCTACTTCCATTCTGGTGA TGTTGGTCTAAATGCATCTCAAGCGATGGACATTATTGTAATTGGCCCAGC CTTGAATACTAATGGCAAGCCGCGAGCTAAACGGGGTTCAGCCACCGATC CCCAGAGTGTGTACGCTAGACATAGGCGAGAAAAAATCAACGAACGACT GAAGAATTTACAAAATCTCGTGCCAAATGGAGCCAAGGTTGACATTGTGA CCATGCTAGACGAAGCCATACACTACGTCAAATTCTTGCAAACTCAAGTT GAGCTGCTGAAATCCGACGAGTTCTGGATGTTCGCAAATCCACACAACTA CAACGGCATAGATATCTCCGATCCCTCTAGCATGCATTCGCCGGAGCTGG AGTCGAATATTTAG Physcomitrella RHD SIX LIKE 7 (PpRSL7) amino acid sequence (SEQ ID NO: 40; ABO84936.1 GI: 140084384) GSATDPQSVYARHRREKINERLKTLQRLVPNGEQVDIVTMLEEAIHFVKFLEF QLELLRSDDRWMFA Physcomitrella RHD SIX LIKE 7 (PpRSL7) nucleotide sequence (SEQ ID NO: 41; EF156399.1 GI: 140084383) Gggtcagctactgatcctcagagtgtgtacgcaaggcatcgccgggagaagattaacgagcgcctaaagacattgcagc ggttggttcctaacggagaacaggtcgacattgtgaccatgctggaagaagccattcactttgtcaaatttttggagttccaac tggagctgttgcgatccgatgatcgctggatgttcgcc Selaginella moelendorfii SmRSLa amino acid sequence (SEQ ID NO: 42) LNTNLKPRAKQGCANDPQSIAARQRRERISDRLKILQELIPNGSKVDLVTMLE KAINYVKFLQLQVKVLMNDEYWPPKGD Selaginella moelendorfii SmRSLa nucleotide sequence(SEQ ID NO: 43) CTCAACACTAATCTTAAGCCGCGAGCAAAGCAAGGTTGTGCTAATGATCC ACAAAGCATTGCTGCCAGACAACGAAGAGAACGGATAAGTGACCGGCTT AAAATCCTGCAGGAGCTCATACCAAATGGATCCAAGGTCGATCTGGTAAC CATGCTGGAGAAGGCCATCAACTACGTCAAGTTCTTGCAATTGCAAGTCA AAGTTCTTATGAACGATGAGTATTGGCCACCAAAGGGAGAT Selaginella moelendorfii SmRSLb amino acid sequence (SEQ ID NO: 44) LNTNLKPRAKQGCANDPQSIAARQRRERISDRLKILQELIPNGSKVDLVTMLE KAINYVKFLQLQVKVLMNDEYWPPKGD Selaginella moelendorfii SmRSLb nucleotide sequence (SEQ ID NO: 45) CTCAACACTAATCTTAAGCCGCGAGCAAAGCAAGGTTGTGCTAATGATCC ACAAAGCATTGCTGCCAGACAACGAAGAGAACGGATAAGTGACCGGCTT AAAATCCTGCAGGAGCTCATACCAAATGGATCCAAGGTCGATCTGGTAAC CATGTTGGAGAAGGCCATCAACTACGTCAAGTTCTTGCAATTGCAAGTCA AAGTTCTTATGAACGATGAGTATTGGCCACCAAAGGGAGAT Selaginella moelendorfii SmRSLc amino acid sequence (SEQ ID NO: 46) LNTNFKPRARQGSANDPQSIAARHRRERISDRLKILQELVPNSTKVDLVTMLE KAINYVKFLQLQVKVLTSDDYWP Selaginella moelendorfii SmRSLc nucleotide sequence (SEQ ID NO: 47) CTCAACACCAATTTCAAGCCTCGAGCCAGGCAGGGAAGCGCCAATGATCC CCAGAGCATCGCTGCTAGACATCGCCGGGAGAGGATCAGTGACAGGCTC AAGATCTTGCAAGAGCTCGTTCCAAACAGCACAAAGGTTGATCTAGTGAC GATGCTGGAGAAGGCCATCAATTACGTCAAGTTCCTCCAGCTGCAAGTTA AGGTGCTTACGTCGGACGACTACTGGCCA Selaginella moelendorfii SmRSLd amino acid sequence (SEQ ID NO: 48) LNTNFKPRARQGSANDPQSIAARHRRERISDRLKILQELVPNSTKVDLVTMLE KAINYVKFLQLQVKVLTSDDYWP Selaginella moelendorfii SmRSLd nucleotide sequence (SEQ ID NO: 49) CTCAACACCAATTTCAAGCCTCGAGCCAGGCAGGGAAGCGCCAATGATCC CCAGAGCATCGCTGCTAGACATCGCCGGGAGAGGATCAGTGACAGGCTC AAGATCTTGCAAGAGCTCGTTCCAAACAGCACAAAGGTTGATCTAGTGAC GATGCTGGAGAAGGCCATCAATTACGTCAAGTTCCTCCAGCTGCAAGTTA AGGTGCTTACGTCGGACGACTATTGGCCA Selaginella moelendorfii SmRSLe amino acid sequence (SEQ ID NO: 50) LNTDGKPRAKRGSATDPQSIYARQRRERINERLRALQGLVPNGAKVDIVTML EEAINYVKFLQLQVKLLSSDEYWMYAPT Selaginella moelendorfii SmRSLe nucleotide sequence (SEQ ID NO: 51) CTAAACACCGACGGAAAGCCACGCGCAAAGCGTGGATCTGCCACGGACC CGCAAAGCATCTACGCTCGGCAAAGAAGAGAAAGGATCAACGAGCGTTT GAGAGCGCTACAAGGACTCGTACCAAACGGAGCGAAGGTTGACATTGTG ACGATGCTCGAGGAAGCCATCAACTATGTCAAGTTTTTGCAGCTGCAAGT AAAGCTGCTCAGCTCGGACGAGTATTGGATGTACGCCCCCACA Selaginella moelendorfii SmRSLf amino acid sequence (SEQ ID NO: 52) LNTNGKPRAKRGSATDPQSVYARHRRERINERLKTLQHLVPNGAKVDIVTM LEEAIHYVKFLQLQVNMLSSDEYWIYAPT Selaginella moelendorfii SmRSLf nucleotide sequence (SEQ ID NO: 53) CTCAACACGAATGGCAAGCCCAGAGCAAAGCGTGGATCTGCAACAGATC CCCAAAGCGTTTACGCAAGGCACCGGAGAGAGAGGATCAACGAGAGGCT CAAAACTTTACAACACCTTGTTCCAAATGGTGCAAAGGTTGACATAGTGA CAATGCTTGAAGAAGCAATACATTACGTGAAGTTTCTACAGCTGCAAGTC AACATGTTAAGCTCTGATGAGTACTGGATTTATGCACCCACA Selaginella moelendorfii SmRSLg amino acid sequence (SEQ ID NO: 54) LNTNGKPRAKRGSATDPQSVYARHRRERINERLKTLQHLVPNGAKVDIVTM LEEAIHYVKFLQLQVNMLSSDEYWTYAPT Selaginella moelendorfii SmRSLg nucleotide sequence (SEQ ID NO: 55) CTCAACACGAATGGCAAGCCCCGAGCAAAGCGTGGATCTGCAACAGATC CCCAAAGCGTTTATGCAAGGCACCGGAGAGAGAGGATCAACGAGAGGCT CAAAACTTTACAACACCTTGTTCCAAATGGTGCAAAGGTTGACATTGTGA CAATGCTTGAAGAAGCAATACATTACGTGAAGTTTCTACAGCTGCAAGTC AACATGTTAAGCTCTGATGAGTACTGGACTTATGCACCCACA Selaginella moelendorfii SmRSLh amino acid sequence (SEQ ID NO: 56) LNTDGKPRAKRGSATDPQSIYARQRRERINERLRALQGLVPNGAKVDIVTML EEAINYVKFLQLQVKLLSSDEYWMYAPT Selaginella moelendorfii SmRSLh nucleotide sequence (SEQ ID NO: 57) CTAAACACCGACGGAAAGCCACGCGCAAAGCGTGGATCTGCCACGGACC CGCAAAGTATCTACGCTCGGCAAAGAAGAGAAAGGATCAACGAGCGTTT GAGAGCGCTACAAGGACTCGTACCAAACGGAGCGAAGGTTGACATTGTG ACGATGCTCGAGGAAGCCATCAACTATGTCAAGTTTTTGCAGCTGCAAGT AAAGCTGCTCAGCTCGGACGAGTATTGGATGTACGCCCCCACA Rice (Oryza sativa subsp. Japonica) OsRSLa amino acid sequence (SEQ ID NO: 58; LOC_Os01g02110.1 11971.m06853) MMAAQASSKRGMLLPREAVLYDDEPSMPLEILGYHGNGVGGGGCVDADYY YSWSGSSSSSSSSVLSFDQAAVGGSGGGCARQLAFHPGGDDDDCAMWMDA AAGAMVENTSVVAGGGNNYCHRLQFHGGAAGFGLASPGSSVVDNGLEIHES NVSKPPPPAAKKRACPSGEARAAGKKQCRKGSKPNKAASASSPSPSPSPSPSP NKEQPQSAAAKVRRERISERLKVLQDLVPNGTKVDLVTMLEKAINYVKFLQL QVKVLATDEFWPAQGGKAPELSQVKDALDAILSSQHPNK* Rice OsRSLa nucleotide sequence (SEQ ID NO: 59; LOC_Os01g02110.1 11971.m06853) ATGATGGCAGCTCAGGCAAGCAGCAAGCGCGGCATGCTGCTGCCACGGG AGGCGGTGCTCTACGACGACGAGCCCTCCATGCCGCTGGAGATCTTGGGC TACCACGGCAATGGCGTCGGCGGCGGTGGCTGCGTTGACGCCGATTACTA CTACAGCTGGTCGGGGTCCAGCTCCAGCTCCAGCTCGTCGGTGCTCAGCT TTGACCAGGCGGCGGTCGGCGGCAGCGGCGGCGGCTGCGCCCGGCAGCT GGCTTTCCATCCCGGCGGCGACGACGACGACTGCGCCATGTGGATGGACG CCGCCGCCGGCGCCATGGTCGAGAACACGTCTGTCGTCGCCGGCGGCGGC AACAACTACTGTCATCGCCTGCAGTTCCACGGCGGCGCCGCCGGTTTCGG ACTCGCGAGCCCAGGCTCGTCGGTCGTTGACAACGGCCTCGAAATCCACG AGAGCAACGTCAGCAAGCCGCCACCGCCGGCAGCCAAGAAGCGCGCATG CCCGAGCGGCGAGGCGAGAGCAGCGGGGAAGAAGCAGTGCAGGAAAGG GAGCAAGCCAAACAAGGCTGCTTCTGCTTCTTCTCCTTCTCCTTCTCCTTC TCCTTCTCCTTCTCCTAACAAGGAACAACCTCAAAGCGCCGCTGCAAAGG TAAGAAGAGAGCGGATCAGTGAGAGGCTCAAAGTTCTTCAGGATCTCGTG CCTAATGGCACAAAGGTAGACTTGGTCACCATGCTAGAAAAGGCGATCAA CTACGTCAAATTCCTCCAGCTGCAAGTGAAGGTTTTGGCTACTGATGAGTT CTGGCCGGCACAAGGAGGGAAAGCACCAGAGCTCTCTCAAGTCAAGGAC GCCTTGGACGCCATCCTATCTTCTCAGCATCCAAACAAATGA Rice OsRSLb amino acid sequence (SEQ ID NO: 60; LOC_Os02g48060.1 11972.m09840) MRMALVRERAMVYGGGCDAEAFGGGFESSQMGYGHDALLDIDAAALFGG YEAAASAGCALVQDGAAGWAGAGASSSVLAFDRAAQAEEAECDAWIEAM DQSYGAGGEAAPYRSTTAVAFDAATGCFSLTERATGGGGGAGGRQFGLLFP STSGGGVSPERAAPAPAPRGSQKRAHAESSQAMSPSKKQCGAGRKAGKAKS APTTPTKDPQSLAAKNRRERISERLRILQELVPNGTKVDLVTMLEKAISYVKF LQLQVKVLATDEFWPAQGGKAPEISQVKEALDAILSSSSPLMGQLMN* Rice OsRSLb nucleotide sequence (SEQ ID NO: 61; LOC_Os02g48060.1 11972.m09840) ATGCGCATGGCGCTGGTGCGGGAGCGCGCGATGGTGTACGGTGGAGGGT GCGACGCCGAGGCGTTCGGCGGCGGGTTCGAGTCGTCCCAGATGGGGTAC GGCCACGACGCGCTGCTCGACATCGACGCGGCGGCGCTGTTCGGGGGGTA CGAGGCGGCCGCCAGCGCCGGGTGCGCCCTCGTGCAGGACGGCGCCGCG GGGTGGGCGGGCGCGGGCGCGTCGTCCTCGGTGCTGGCGTTCGACCGCGC CGCTCAGGCGGAGGAGGCCGAGTGCGACGCGTGGATCGAAGCCATGGAC CAGAGCTACGGCGCCGGCGGCGAGGCGGCGCCGTACCGGTCGACGACGG CCGTCGCCTTCGACGCGGCCACCGGCTGCTTCAGCCTGACGGAGAGAGCC ACCGGCGGCGGCGGCGGCGCGGGTGGGCGGCAGTTCGGGCTGCTGTTCCC GAGCACGTCGGGCGGCGGCGTCTCCCCCGAACGCGCCGCGCCGGCGCCG GCGCCCCGCGGCTCGCAGAAGCGGGCCCACGCGGAGTCGTCGCAGGCCA TGAGCCCTAGCAAGAAGCAGTGCGGCGCCGGCAGGAAGGCGGGCAAGGC CAAGTCGGCGCCGACCACCCCAACCAAGGACCCGCAAAGCCTCGCGGCC AAGAATCGGCGCGAGAGGATCAGCGAGCGGCTGCGGATCCTGCAGGAGC TCGTGCCCAACGGCACCAAGGTCGACCTCGTCACCATGCTCGAGAAGGCC ATCAGCTACGTCAAGTTCCTCCAGCTTCAAGTCAAGGTTCTTGCGACGGA CGAGTTCTGGCCGGCGCAGGGAGGGAAGGCGCCGGAGATATCCCAGGTG AAGGAGGCGCTCGACGCCATCTTGTCGTCGTCGTCGCCGCTGATGGGACA ACTCATGAACTGA Rice OsRSLc amino acid sequence (SEQ ID NO: 62; LOC_Os06g30090.1 11976.m07553) MAMVAGDEAMSVPWHDVGVVVDPEAAGTAPFDAGAGYVPSYGQCQYYY YYDDHHHHPCSTELIHAGDAGSAVAVAYDGVDGWVHAAAAATSPSSSSALT FDGHGAEEHSAVSWMDMDMDAHGAAPPLIGYGPTAATSSPSSCFSSGGSGD SGMVMVTTTTPRSAAASGSQRRARPPPSPLQGSELHEYSKKQRANNKETQSS AAKSRRERISERLRALQELVPSGGKVDMVTMLDRAISYVKFMQMQLRVLET DAFWPASDGATPDISRVKDALDAIILSSSSPSQKASPPRSG* Rice OsRSLc nucleotide sequence (SEQ ID NO: 63; LOC_Os06g30090.1 11976.m07553) ATGGCTATGGTGGCCGGCGACGAGGCGATGTCAGTGCCATGGCACGACGT CGGCGTCGTCGTCGACCCCGAGGCGGCCGGGACGGCGCCGTTCGACGCCG GCGCCGGCTATGTCCCATCGTACGGTCAGTGCCAATACTACTACTACTAC GACGACCACCACCACCACCCGTGCAGCACGGAGCTGATCCACGCGGGCG ACGCTGGCAGTGCGGTTGCGGTTGCGTACGACGGCGTCGACGGCTGGGTT CACGCCGCCGCCGCAGCCACCTCCCCGTCCTCGTCATCTGCGCTCACCTTC GATGGTCACGGCGCCGAGGAGCACAGCGCAGTGTCGTGGATGGACATGG ACATGGACGCGCACGGCGCCGCGCCTCCCCTAATCGGCTACGGCCCGACG GCGGCGACCTCCTCCCCCTCCTCCTGCTTCAGCTCCGGCGGCTCCGGCGAC AGCGGCATGGTGATGGTGACCACCACCACCCCGAGGAGCGCCGCCGCCTC TGGTTCGCAGAGGCGGGCACGCCCGCCGCCGTCGCCGTTGCAGGGATCAG AGCTGCACGAGTACTCCAAGAAGCAGCGCGCCAACAACAAGGAGACACA GAGCTCAGCTGCCAAGAGCCGGCGGGAGAGGATCAGCGAGCGGCTGAGG GCGCTGCAGGAGCTGGTGCCGAGCGGCGGGAAGGTGGACATGGTGACCA TGCTGGACAGGGCCATCAGCTACGTCAAGTTCATGCAGATGCAGCTCAGG GTGCTGGAGACCGACGCGTTCTGGCCGGCGTCCGACGGCGCCACGCCGGA CATCTCCCGGGTCAAGGACGCGCTCGACGCCATCATCCTCTCCTCGTCCTC GCCCTCGCAAAAGGCTTCTCCTCCTCGGTCGGGCTAG Rice OsRSLd amino acid sequence (SEQ ID NO: 64; LOC_Os03g10770.1 11973.m06529) MEDSEAMAQLLGVQYFGNDQEQQQPAAAAPPAMYWPAHDAADQYYGSAP YCYMQQQQHYGCYDGGAMVAGGDFFVPEEQLVADPSFMVDLNLEFEDQH GGDAGGAGSSAAAAAAATKMTPACKRKVEDHKDESCTDNVARKKARSTA ATVVQKKGNKNAQSKKAQKGACSRSSNQKESNGGGDGGNVQSSSTNYLSD DDSLSLEMTSCSNVSSASKKSSLSSPATGHGGAKARAGRGAATDPQSLYARK RRERINERLKILQNLIPNGTKVDISTMLEEAVHYVKFLQLQIKLLSSDDMWMF APIAYNGVNVGLDLKISPPQQQ* Rice OsRSLd nucleotide sequence (SEQ ID NO: 65; LOC_Os03g10770.1 11973.m06529) ATGGAGGACTCGGAGGCGATGGCGCAGCTGCTCGGCGTGCAGTACTTCGG CAATGACCAGGAGCAGCAGCAGCCGGCGGCGGCGGCGCCGCCGGCGATG TACTGGCCGGCGCACGACGCGGCCGACCAGTACTACGGCTCGGCGCCATA CTGCTACATGCAGCAGCAGCAGCATTACGGGTGCTACGACGGCGGCGCG ATGGTGGCCGGCGGCGACTTCTTCGTGCCGGAGGAGCAGCTGGTGGCCGA CCCGAGCTTCATGGTGGACCTGAACCTCGAGTTCGAGGACCAGCACGGCG GCGATGCTGGCGGCGCTGGGAGCAGCGCCGCCGCCGCCGCCGCCGCCAC CAAGATGACACCGGCGTGCAAGAGGAAGGTTGAGGATCACAAGGATGAG AGCTGCACGGACAACGTCGCGAGGAAGAAGGCGCGCTCCACGGCAGCAA CAGTGGTGCAGAAGAAGGGTAATAAGAACGCGCAGTCAAAGAAGGCGCA GAAGGGCGCGTGCAGCCGGAGCAGCAACCAGAAGGAGAGCAATGGCGG CGGCGACGGCGGCAATGTGCAGAGCTCGAGCACCAACTACCTCTCTGATG ACGACTCGCTGTCGCTGGAGATGACTTCGTGCAGCAACGTGAGCTCGGCG TCCAAGAAGTCGTCGTTGTCATCGCCGGCGACCGGGCACGGCGGCGCGAA GGCGAGGGCCGGGCGCGGGGCGGCGACCGATCCGCAAAGCCTCTATGCC AGGAAGAGGAGAGAAAGGATCAATGAACGGCTAAAGATACTGCAGAATC TTATCCCAAATGGAACCAAGGTGGACATCAGCACGATGCTTGAAGAAGCA GTTCACTACGTCAAGTTCTTGCAGCTCCAAATCAAGCTTCTGAGCTCGGAT GATATGTGGATGTTCGCGCCGATCGCGTACAACGGGGTCAACGTCGGGCT CGACCTCAAGATCTCTCCACCGCAGCAGCAATGA Rice OsRSLe amino acid sequence (SEQ ID NO: 66; LOC_Os03g42100.1 11973.m09268) MESGGVIAEAGWSSLDMSSQAEESEMMAQLLGTCFPSNGEDDHHQELPWSV DTPSAYYLHCNGGSSSAYSSTTSSNSASGSFTLIAPRSEYEGYYVSDSNEAAL GISIQEQGAAQFMDAILNRNGDPGFDDLADSSVNLLDSIGASNKRKIQEQGRL DDQTKSRKSAKKAGSKRGKKAAQCEGEDGSIAVTNRQSLSCCTSENDSIGSQ ESPVAAKSNGKAQSGHRSATDPQSLYARKRRERINERLKILQNLVPNGTKVDI STMLEEAMHYVKFLQLQIKLLSSDEMWMYAPIAYNGMNIGIDLNLSQH* Rice OsRSLe nucleotide sequence (SEQ ID NO: 67; LOC_Os03g42100.1 11973.m09268) ATGGAGTCCGGAGGGGTGATCGCGGAGGCGGGGTGGAGCTCGCTCGACA TGTCGTCGCAGGCCGAGGAGTCGGAGATGATGGCGCAGCTGCTTGGAACC TGCTTCCCCTCCAATGGCGAGGATGATCATCACCAAGAGCTTCCTTGGTC GGTTGACACCCCCAGTGCCTACTACCTCCATTGCAATGGAGGTAGCTCAA GTGCATACAGCTCTACCACTAGCAGCAACAGTGCTAGTGGTAGCTTCACT CTCATTGCACCAAGATCTGAGTATGAGGGGTACTATGTGAGTGACTCTAA TGAGGCGGCCCTCGGGATCAGCATCCAGGAGCAAGGTGCAGCTCAGTTCA TGGATGCCATTCTCAACCGGAACGGCGATCCGGGCTTCGATGATCTCGCT GACTCGAGCGTTAATCTGCTGGATTCCATCGGCGCTTCTAACAAGAGAAA GATTCAGGAGCAAGGCAGGCTAGATGACCAAACGAAAAGTAGGAAATCT GCGAAGAAGGCTGGCTCGAAGCGGGGAAAGAAGGCGGCGCAATGTGAAG GTGAAGATGGCAGCATTGCTGTCACCAACAGGCAAAGCTTGAGCTGCTGC ACCTCTGAAAATGATTCGATTGGTTCTCAAGAATCTCCTGTTGCTGCTAAG TCGAATGGCAAGGCTCAATCTGGCCATCGGTCAGCAACCGATCCCCAGAG CCTCTATGCAAGGAAAAGAAGAGAGAGGATCAATGAGAGGCTCAAGATT CTGCAGAACCTTGTACCAAATGGAACCAAAGTAGATATCAGCACTATGCT TGAAGAGGCAATGCATTACGTGAAGTTCTTGCAGCTTCAAATCAAGCTCC TCAGCTCTGATGAAATGTGGATGTACGCACCGATTGCTTACAACGGGATG AACATCGGGATCGATTTGAACCTCTCTCAGCATTGA Rice OsRSLf amino acid sequence (SEQ ID NO: 68; LOC_Os11g41640.1 11981.m08005) MDARCANIWSSADARSEESEMIDQLKSMFWSSTDAEINFYSPDSSVNSCVTTS TMPSSLFLPLMDDEGFGTVQLMHQVITGNKRMFPMDEHFEQQQKKPKKKTR TSRSVSSSSTITDYETSSELVNPSCSSGSSVGEDSIAATDGSVVLKQSDNSRGH KQCSKDTQSLYAKRRRERINERLRILQQLVPNGTKVDISTMLEEAVQYVKFL QLQIKLLSSDDTWMFAPLAYNGMNMDLGHTLAENQE* Rice OsRSLf nucleotide sequence (SEQ ID NO: 69; LOC_Os11g41640.1 11981.m08005) ATGGATGCAAGGTGTGCAAACATCTGGAGCTCTGCTGATGCAAGGAGTGA GGAATCTGAGATGATTGATCAACTAAAGTCCATGTTCTGGAGCAGCACTG ATGCTGAAATCAACTTTTATTCTCCTGACAGTAGTGTAAATTCTTGTGTCA CAACTAGCACAATGCCTAGCAGCTTGTTTCTTCCTCTGATGGATGATGAGG GATTTGGCACAGTGCAATTGATGCATCAGGTCATCACTGGGAACAAGAGG ATGTTCCCCATGGATGAGCACTTTGAGCAGCAGCAGAAGAAGCCGAAGA AGAAAACCCGAACTTCTCGCTCGGTATCAAGTAGTTCAACCATTACTGAC TATGAGACTAGCTCTGAACTTGTCAATCCTAGCTGTTCCTCCGGGAGCAGC GTCGGAGAGGATTCAATTGCTGCAACTGATGGATCTGTAGTGCTGAAACA AAGTGACAATTCAAGAGGCCATAAGCAGTGCTCCAAGGATACACAAAGC CTCTATGCTAAGAGGAGAAGGGAAAGGATTAATGAGAGACTGAGAATAC TTCAGCAGCTTGTTCCCAATGGCACTAAAGTTGACATCAGCACAATGCTG GAGGAAGCAGTTCAGTATGTCAAGTTTTTGCAGTTGCAAATAAAGCTATT GAGCTCTGACGACACATGGATGTTTGCGCCCCTAGCCTATAATGGCATGA ACATGGATCTCGGTCATACTCTTGCTGAAAACCAAGAATGA Rice OsRSLg amino acid sequence (SEQ ID NO: 70; LOC_Os12g32400.1 11982.m07043) MECSSFEAICNESEMIAHLQSLFWSSSDADPCFGSSSFSLISSEGYDTMTTEFV NSSTNVCFDYQDDSFVSAEETTIGNKRKVQMDTENELMTNRSKEVRTKMSV SKACKHSVSAESSQSYYAKNRRQRINERLRILQELIPNGTKVDISTMLEEAIQY VKFLHLQIKLLSSDEMWMYAPLAFDSGNNRLYQNSLSQE* Rice OsRSLg nucleotide sequence (SEQ ID NO: 71; LOC_Os12g32400.1 11982.m07043) ATGGAATGCAGCTCCTTTGAAGCAATCTGCAATGAGTCGGAGATGATTGC GCATTTGCAGTCATTGTTCTGGAGCAGCAGCGATGCTGATCCTTGTTTTGG TAGCTCATCATTTTCTCTCATCAGTAGTGAGGGCTACGACACAATGACCAC AGAGTTTGTGAATAGCAGCACAAATGTATGTTTTGATTACCAAGATGATA GCTTCGTTTCAGCAGAGGAGACTACCATTGGTAACAAGAGAAAAGTTCAG ATGGATACTGAGAATGAGCTGATGACGAACCGCAGCAAGGAAGTTCGCA CCAAGATGTCGGTGTCAAAAGCATGCAAACATTCTGTTTCTGCAGAGAGC TCACAGTCTTATTATGCAAAGAACAGGAGACAGAGGATCAATGAGAGATT GAGAATACTGCAAGAACTGATCCCTAATGGAACAAAAGTTGACATCAGC ACAATGTTGGAGGAAGCAATTCAGTATGTCAAGTTTCTACACCTGCAAAT CAAGCTCTTGAGCTCTGATGAAATGTGGATGTATGCGCCCCTTGCTTTTGA CAGTGGTAACAACAGGCTCTATCAGAACTCTCTGTCACAAGAGTAG Rice OsRSLh amino acid sequence (SEQ ID NO: 72; LOC_Os12g39850.1 11982.m07769) MEGGGLIADMSWTVFDLPSHSDESEMMAQLFSAFPIHGEEEGHEQLPWFDQS SNPCYYSCNASSTAYSNSNASSIPAPSEYEGYCFSDSNEALGVSSSIAPHDLSM VQVQGATEFLNVIPNHSLDSFGNGELGHEDLDSVSGTNKRKQSAEGEFDGQT RGSKCARKAEPKRAKKAKQTVEKDASVAIPNGSCSISDNDSSSSQEVADAGA TSKGKSRAGRGAATDPQSLYARKRRERINERLKTLQNLVPNGTKVDISTMLE EAVHYVKFLQLQIKLLSSDEMWMYAPIAYNGMNIGLDLNIDT* Rice OsRSLh nucleotide sequence (SEQ ID NO: 73; LOC_Os12g39850.1 11982.m07769) ATGGAGGGTGGAGGACTGATCGCCGATATGAGCTGGACCGTCTTCGACTT GCCATCGCACAGCGATGAGTCGGAGATGATGGCGCAGCTCTTCAGTGCAT TCCCCATCCATGGTGAGGAGGAAGGCCATGAGCAGCTCCCATGGTTTGAT CAATCTTCCAATCCATGCTACTATAGCTGCAATGCTAGCAGCACTGCATA CAGCAACAGCAATGCTAGTAGCATTCCTGCTCCATCTGAGTATGAAGGAT ACTGCTTCAGTGACTCAAATGAGGCCCTGGGTGTCAGCTCCAGCATTGCA CCACATGACCTGAGCATGGTCCAGGTGCAAGGTGCAACTGAGTTTCTGAA TGTGATCCCAAACCATTCCCTTGATTCATTCGGTAATGGCGAGCTGGGCCA CGAGGATCTTGATTCGGTTAGTGGGACTAACAAGAGAAAACAGTCGGCA GAAGGAGAATTTGATGGCCAAACAAGAGGTTCAAAATGCGCGAGAAAGG CTGAACCGAAGCGAGCGAAGAAGGCCAAGCAAACTGTGGAGAAGGATGC AAGTGTTGCCATCCCAAATGGGAGCTGTTCCATTTCTGACAATGATTCCAG TTCATCCCAGGAGGTTGCAGATGCTGGTGCTACTTCGAAAGGCAAATCCC GGGCTGGCCGCGGAGCAGCCACTGATCCCCAGAGCCTCTATGCAAGGAA AAGGAGAGAGAGGATCAATGAGAGGCTCAAGACACTTCAGAACCTTGTG CCCAATGGCACCAAAGTTGATATCAGCACCATGCTTGAGGAGGCAGTCCA CTATGTGAAGTTCCTGCAGCTTCAGATCAAGCTCCTCAGCTCCGATGAAAT GTGGATGTATGCGCCAATTGCGTACAACGGGATGAACATTGGGCTCGATC TGAACATTGATACATGA Rice OsRSLi amino acid sequence (SEQ ID NO: 74; LOC_Os07g39940.1 11977.m08236) MAQFLGAHGDHCFTYEQMDESMEAMAAMFLPGLDTDSNSSSGCLNYDVPP QCWPQHGHSSSVTSFPDPAHSYGSFEFPVMDPFPIADLDAHCAIPYLTEDLISP PHGNHPSARVEEATKVVTPVATKRKSSAAMTASKKSKKAGKKDPIGSDEGG NTYIDTQSSSSCTSEEGNLEGNAKPSSKKMGTRANRGAATDPQSLYARKRRE RINERLRILQNLVPNGTKVDISTMLEEAVQYVKFLQLQIKLLSSDDTWMYAPI AYNGVNISNIDLNISSLQK* Rice OsRSLi nucleotide sequence (SEQ ID NO: 75; LOC_Os07g39940.1 11977 .m08236) ATGGCGCAGTTTCTTGGAGCTCATGGTGATCACTGCTTCACCTACGAGCA AATGGATGAGTCCATGGAGGCAATGGCAGCGATGTTCTTGCCTGGCCTTG ACACCGACTCCAATTCTTCTTCTGGTTGTCTCAACTACGATGTGCCTCCAC AATGCTGGCCTCAGCATGGCCATAGCTCTAGCGTCACCAGCTTCCCTGAT CCAGCTCATAGCTATGGAAGCTTTGAGTTCCCGGTCATGGATCCGTTCCCG ATCGCCGATCTCGACGCGCATTGCGCCATCCCCTACCTTACTGAGGATCTG ATCAGCCCTCCACATGGCAACCATCCATCAGCAAGAGTGGAAGAAGCTAC AAAGGTTGTTACACCAGTGGCTACCAAGAGGAAGTCTAGTGCTGCCATGA CGGCATCAAAGAAGAGCAAGAAGGCTGGCAAAAAAGATCCTATTGGCAG CGACGAAGGCGGCAACACCTACATTGATACGCAAAGTTCTAGCAGTTGCA CCTCAGAGGAAGGAAACCTGGAGGGCAACGCGAAGCCGAGCTCGAAGAA GATGGGTACTAGGGCCAACCGTGGGGCGGCAACCGATCCCCAGAGTCTCT ATGCAAGGAAGAGGAGAGAGAGGATCAATGAAAGATTGAGGATCCTGCA GAACTTGGTTCCCAATGGAACAAAGGTTGACATCAGTACAATGCTGGAGG AAGCAGTGCAGTATGTCAAATTTTTGCAACTTCAGATTAAGTTGCTAAGCT CTGATGACACGTGGATGTATGCACCAATCGCTTACAATGGAGTCAACATC AGCAATATTGATCTGAACATCTCTTCTCTGCAAAAATAA Populus trichocarpa PtRSLa amino acid sequence (SEQ ID NO: 76) MALAKDRMGSVQTCPYNGNVMGDFSSMGSYGFDEYQKVAFYEEGNSTFEK TSGLMIKNLAMTSSPSSLGSPSSAISGELVFQATDHQAEEAHSLISFKGIGFDNI MHNNGSLLSFEQSSRVSQTSSQKDDYSAWEGNLSYNYQWNEMNPKCNTSPR LMEDFNCFQRAGNFISMTGKENHGDWLYAESTIVADSIQDSATPDASSFHKR PNMGESMQALKKQCNNATKKPKPKSAAGPAKDLQSIAAKNRRERISERLKV LQDLVPNGSKVDLVTMLEKAISYVKFLQLQVKVLATDELWPVQGGKAPDIS QVKEAIDALLSSQTKDGNSSSSPK* Populus trichocarpa PtRSLa nucleotide sequence (SEQ ID NO: 77) ATGGCACTTGCCAAGGACCGTATGGGATCGGTTCAAACTTGCCCCTATAA TGGAAATGTGATGGGGGATTTTTCCTCCATGGGGTCTTACGGATTTGATGA ATATCAGAAGGTAGCATTTTATGAAGAGGGAAATAGCACCTTTGAGAAAA CCAGTGGGCTTATGATCAAGAATTTAGCTATGACCTCTTCTCCTTCTTCTC TTGGCAGTCCGAGCAGCGCGATTTCTGGTGAATTAGTGTTTCAGGCTACTG ACCATCAAGCTGAGGAAGCTCATTCTTTGATCAGCTTCAAAGGTATCGGA TTCGATAACATCATGCATAATAATGGATCTTTGCTTAGCTTTGAGCAAAGT AGTAGGGTTTCTCAAACTAGTAGCCAGAAAGATGACTACTCAGCCTGGGA GGGTAATTTGAGTTACAACTACCAGTGGAACGAAATGAATCCAAAATGTA ACACAAGTCCTCGGTTGATGGAAGATTTTAATTGCTTTCAAAGAGCTGGC AACTTCATTTCCATGACTGGAAAGGAAAATCATGGTGATTGGTTATACGC TGAATCCACAATTGTTGCTGATAGCATTCAGGATTCTGCAACACCAGATG CCAGCAGCTTCCATAAGCGTCCTAATATGGGAGAGAGTATGCAGGCTCTA AAGAAGCAATGCAACAATGCAACAAAAAAGCCAAAACCGAAGTCCGCAG CAGGTCCAGCTAAGGATCTACAGAGTATTGCTGCCAAGAATCGACGAGAG AGGATTAGCGAGAGGCTTAAGGTATTGCAGGATTTAGTCCCTAATGGCTC AAAGGTTGATTTGGTTACTATGCTAGAGAAAGCCATTAGTTATGTTAAGTT TCTTCAATTGCAAGTAAAGGTGTTAGCCACTGATGAATTATGGCCAGTTC AAGGTGGTAAAGCTCCTGATATTTCTCAAGTAAAGGAAGCCATCGATGCC CTACTCTCATCTCAGACTAAAGACGGAAACTCAAGCTCAAGCCCAAAGTA A Populus trichocarpa PtRSLb amino acid sequence (SEQ ID NO: 78) MALAKDRMDSVQTCALYGNVMGDLSSLGPNYRFDEEGDRNFEKNSALMIK NLAMSPSPPSLGSPSSANSGELVFQATDNQVEEAHSLINFKGTGFDSIMHANG SLISFEQSNRVSQTSSHKDDYSAWEGNLSCNYQWNQINPKCNANPRLMEDLN CYQSASNFNSITNSAEKENHGDWLYTHESTIVTDSIPDSATPDASSFHKRPNM GESMQALKKQRDSATKKPKPKSAGPAKDPQSIAAKNRRERISERLKMLQDLV PNGSKVDLVTMLEKAISYVKFLQLQVKVLATDEFWPVQGGKAPDISQVKGAI DATLSSQTKDRNSNSSSK* Populus trichocarpa PtRSLb nucleotide sequence (SEQ ID NO: 79) ATGGCACTTGCCAAGGACCGTATGGATTCGGTTCAAACTTGCGCCCTTTAT GGAAATGTGATGGGGGATCTTTCCTCCTTGGGGCCTAATTATAGATTTGAT GAAGAGGGAGATAGGAACTTTGAGAAAAATAGTGCGCTTATGATCAAGA ATTTAGCTATGAGCCCTTCTCCTCCTTCTCTTGGCAGTCCAAGCAGTGCAA ATTCTGGTGAACTAGTGTTTCAGGCTACTGACAATCAAGTTGAGGAAGCT CATTCTTTGATCAACTTCAAAGGTACCGGATTTGATAGTATCATGCATGCT AATGGATCTTTGATTAGCTTTGAGCAAAGTAATAGGGTTTCTCAAACTAGT AGTCACAAAGATGACTACTCTGCTTGGGAGGGTAATTTGAGTTGCAATTA CCAGTGGAACCAAATCAATCCAAAATGTAACGCAAATCCTCGGTTGATGG AAGATCTTAATTGCTATCAAAGTGCAAGCAACTTCAACTCCATAACCAAC AGTGCTGAAAAGGAAAACCATGGTGATTGGTTATACACTCATGAATCCAC AATTGTTACTGATAGCATTCCCGATTCTGCAACACCAGATGCCAGCAGCTT CCATAAGCGTCCCAATATGGGAGAGAGTATGCAGGCTCTAAAGAAGCAA CGCGACAGCGCCACAAAAAAGCCGAAACCCAAGTCTGCTGGTCCAGCTA AGGATCCACAAAGTATTGCTGCCAAGAATCGACGAGAGCGGATTAGCGA GCGCCTTAAGATGTTGCAGGATTTAGTCCCTAACGGCTCCAAGGTTGATTT GGTTACTATGCTAGAGAAAGCCATTAGTTATGTTAAGTTTCTTCAATTGCA AGTAAAGGTGTTGGCCACTGATGAATTCTGGCCAGTTCAAGGTGGTAAAG CTCCTGATATTTCTCAAGTAAAGGGAGCCATTGATGCCACACTCTCATCTC AGACTAAAGACAGAAATTCAAACTCAAGCTCAAAGTGA Populus trichocarpa PtRSLc amino acid sequence (SEQ ID NO: 80) MAEGEWSSLGGMYTSEEADFMAQLLGNCPNQVDSSSNFGVPSSFWPNHEPT TDMEGANECLFYSLDFANINLHHFSQGSSSYSGGSGILFPNTSQDSYYMSDSH PILANNNSSMSMDFCMGDSYLVEGDDCSNQEMSNSNEEPGGNQTVAALPEN DFRAKREPEMPASELPLEDKSSNPPQISKKRSRNSGDAQKNKRNASSKKSQK VASTSNNDEGSNAGLNGPASSGCCSEDESNASHELNRGASSSLSSKGTATLNS SGKTRASRGAATDPQSLYARKRRERINERLRILQTLVPNGTKVDISTMLEEAV QYVKFLQLQIKLLSSEDLWMYAPIAYNGMDIGLDHLKVTAP* Populus trichocarpa PtRSLc nucleotide sequence (SEQ ID NO: 81) ATGGCAGAGGGAGAGTGGAGTTCTCTTGGTGGAATGTACACTAGTGAGGA GGCTGATTTCATGGCACAGTTGCTTGGTAACTGTCCTAATCAGGTTGATTC AAGTTCAAACTTTGGAGTTCCATCTAGTTTCTGGCCTAACCACGAACCAAC AACGGACATGGAAGGGGCTAATGAATGTTTATTTTATTCTTTGGATTTTGC TAATATTAATTTGCACCATTTTTCACAAGGGAGTAGTAGTTATAGTGGTGG CAGTGGCATTCTTTTTCCCAACACAAGCCAAGATAGCTACTACATGAGTG ATTCTCATCCAATTTTGGCTAACAATAATAGCTCAATGTCAATGGATTTTT GCATGGGAGACTCATATCTCGTTGAAGGCGATGACTGCTCAAACCAAGAA ATGAGCAATAGCAATGAGGAGCCTGGTGGAAACCAGACTGTAGCTGCTCT TCCTGAAAACGATTTTCGGGCCAAGAGAGAACCAGAGATGCCAGCTTCTG AACTACCCCTGGAAGACAAAAGCAGCAACCCACCTCAGATTTCTAAGAA AAGATCACGAAATTCAGGAGATGCTCAAAAGAACAAGAGGAATGCAAGT TCAAAGAAGAGCCAGAAGGTTGCCTCGACTAGCAACAATGATGAAGGAA GTAATGCTGGCCTTAATGGGCCTGCCTCAAGCGGTTGCTGCTCAGAGGAT GAATCCAATGCCTCTCATGAGCTCAATAGAGGAGCGAGTTCAAGTTTGAG CTCGAAAGGGACTGCAACTCTCAACTCAAGTGGCAAAACAAGAGCCAGC AGGGGGGCAGCCACTGATCCCCAGAGTCTCTATGCAAGGAAAAGAAGAG AAAGAATAAATGAGAGGCTGAGAATTCTACAAACCCTTGTCCCCAACGGA ACAAAGGTTGACATTAGCACAATGCTTGAAGAAGCTGTCCAGTATGTGAA GTTTTTGCAACTCCAAATTAAGCTGCTAAGCTCTGAGGACTTGTGGATGTA TGCGCCTATCGCTTACAACGGGATGGACATCGGTCTTGATCATCTGAAGG TTACCGCACCATGA Populus trichocarpa PtRSLd amino acid sequence (SEQ ID NO: 82) MEPIGATAEGEWSSLSGMYTSEEADFMEQLLVNCPPNQVDSSSSFGVPSSFW PNHESTMNMEGANECLLYSLDIADTNLYHFSQVSSGYSGELSNGNVEESGGN QTVAALPEPESNLQPKRESKMPASELPLEDKSRKPPENSKKRSRRTGDAQKN KRNVRSKKSQKVASTGNNDEESNGGLNGPVSSGCCSEDESNASQELNGGASS SLSSKGTTTLNSSGKTRASKGAATDPQSLYARKRRERINERLRILQNLVPNGT KVDISTMLEEAVQYVKFLQLQIKLLSSEDLWMYAPIAYNGMDIGLDHLKLTT PRRL* Populus trichocarpa PtRSLd nucleotide sequence (SEQ ID NO: 83) ATGGAGCCTATTGGAGCCACTGCGGAGGGAGAGTGGAGTTCTCTTAGTGG AATGTACACAAGTGAGGAGGCTGATTTCATGGAACAGTTGCTTGTCAACT GTCCTCCTAATCAGGTTGATTCAAGTTCAAGCTTTGGAGTTCCATCTAGTT TTTGGCCTAACCATGAATCAACAATGAACATGGAAGGGGCCAATGAATGT TTATTGTATTCTTTGGATATTGCTGATACTAATCTGTACCATTTTTCACAAG TGAGCAGTGGTTATAGTGGTGAATTGAGCAATGGAAATGTGGAAGAGTCT GGTGGAAACCAGACTGTAGCTGCTCTTCCTGAACCTGAAAGCAATTTGCA ACCCAAGAGAGAATCAAAGATGCCAGCATCTGAACTACCCCTGGAAGAT AAAAGCAGAAAGCCACCTGAGAATTCCAAGAAAAGATCACGACGTACGG GAGATGCCCAAAAGAACAAGAGGAATGTAAGGTCAAAGAAGAGCCAGA AGGTTGCCTCGACTGGCAACAATGATGAAGAAAGCAATGGTGGCCTTAAT GGTCCTGTCTCAAGCGGTTGCTGCTCAGAGGATGAATCCAATGCCTCCCA GGAGCTCAATGGAGGAGCGAGTTCAAGTTTGAGCTCAAAAGGGACAACA ACTCTCAACTCAAGTGGCAAAACAAGAGCCAGTAAGGGGGCAGCCACTG ATCCCCAGAGCCTCTATGCAAGGAAAAGAAGAGAAAGAATAAATGAGAG GCTGAGAATTCTACAAAACCTTGTCCCCAATGGAACAAAGGTTGACATTA GCACAATGCTTGAAGAGGCTGTCCAGTATGTGAAGTTTTTGCAACTCCAA ATTAAGCTGCTAAGCTCTGAAGACCTGTGGATGTATGCTCCTATCGCGTAC AATGGTATGGACATCGGTCTTGATCATCTGAAGCTTACCACACCAAGACG ATTGTAG Populus trichocarpa PtRSLe amino acid sequence (SEQ ID NO: 84) MNTQAMEAFRDGELWNFSRMFSMEEPDCTPELLGQCSFLQDTDEGLHFTIPS AFFPAPESDASMAEDESLFYSWHTPNPNLHFDSQESSNNSNSSSSVFLPYSSHE SYFFNDSNPIQATNNNSMSMDIMDEENIGLFMPLFPEIAMAETACMNGDMSG DKTGDLDDNLKPAANDVLAKGLQLKRKLDVPEPIANTLDDMKKKARVTRN VQKTRKVGQSKKNQKNAPDISHDEEESNAGPDGQSSSSCSSEEDNASQDSDS KVSGVLNSNGKTRATRGAATDPQSLYARKRRERINERLKILQNLVPNGTKVD ISTMLEEAVHYVNFLQLQIKLLSSDDLWMYAPLAYNGIDIGLNQKLSMFL* Populus trichocarpa PtRSLe nucleotide sequence (SEQ ID NO: 85) ATGAATACGCAGGCTATGGAAGCCTTTCGTGATGGAGAATTATGGAACTT CAGCAGAATGTTCTCCATGGAAGAGCCTGATTGCACCCCAGAATTACTTG GTCAGTGCTCTTTTCTTCAGGATACTGATGAAGGATTGCATTTTACAATCC CATCAGCTTTCTTCCCTGCTCCTGAATCCGACGCGAGCATGGCTGAGGAC GAGAGTTTGTTTTATTCTTGGCATACTCCCAACCCCAATTTGCATTTTGATT CTCAAGAAAGTAGTAATAACAGTAATTCTAGCAGTAGTGTATTTCTTCCCT ATTCCAGCCATGAATCCTACTTCTTCAATGATTCTAATCCCATTCAAGCTA CGAACAATAACTCTATGTCCATGGATATTATGGATGAGGAAAATATTGGC TTGTTTATGCCACTTTTTCCTGAAATTGCAATGGCAGAAACTGCCTGTATG AATGGAGATATGAGCGGTGACAAAACAGGAGATTTAGATGATAATCTGA AGCCAGCAGCTAATGATGTTCTGGCCAAGGGATTGCAGCTCAAAAGGAA GCTTGATGTTCCAGAACCAATAGCCAACACATTGGACGACATGAAGAAAA AAGCCCGGGTTACAAGAAATGTGCAAAAGACTAGGAAGGTTGGACAGTC AAAAAAAAATCAGAAGAACGCACCAGATATTAGCCATGATGAAGAAGAG AGTAATGCTGGACCAGACGGACAAAGTTCCAGCAGTTGTAGTTCAGAAGA GGACAATGCCTCTCAGGATTCTGATTCCAAGGTTTCTGGAGTTCTCAATTC CAATGGAAAAACAAGAGCTACTAGGGGAGCTGCCACAGACCCCCAGAGC CTTTATGCAAGGAAAAGAAGGGAGAGGATAAACGAGAGACTGAAAATCT TGCAGAATCTTGTCCCTAACGGAACCAAGGTTGATATCAGCACGATGCTA GAAGAGGCAGTCCATTACGTAAACTTTTTGCAGCTTCAAATCAAGCTTTTG AGCTCGGATGATCTATGGATGTATGCACCTCTGGCTTACAATGGAATAGA TATTGGACTCAACCAGAAGCTCTCTATGTTTCTATGA Musa acuminata MaRSLa amino acid sequence (SEQ ID NO: 86; GI102139852, ABF70010.1) MAQESTWSSFDATMLAEEESRMIAQLLSNYQCFGEQDRDVGCCELPPSSCCS SHAADSCYCWSANENSNPGLCYWSQSGDESDGAHAIGTVPVFTNHCLVGDQ VAVNQTLSIHEPTAAHAEMPKRKIESHASEDDFRRQSSKKKLQAPTNALKSV KKARPGRNQKSIVCGDEEENNARSSGRSCCSYSSEEDSQAFQADLNAKTRSN RWPATDPQSLYAKQRRERINARLRTLQNLVPNGTKVDISTMLEEAVRYVKFL QLQIKLLSSDELWMYAPVVHSGMIDGQVNSEIFVSANTRNEWF* Musa acuminata MaRSLa nucleotide sequence (SEQ ID NO: 87). atggctcaggagtcaacttggagctcgtttgatgctacaatgcttgctgaggaggagtcccgaatgatcgcacaattgctca gcaactaccagtgttttggcgagcaagatcgagatgttggatgctgtgaactcccgccatcgtcttgttgttcttctcatgcag ctgattcatgttactgttggtcagcaaatgagaacagtaacccgggtttgtgctactggtctcagagtggagatgaatccgat ggagcacatgcaatcggcactgtgccggtcttcacgaaccattgcttggtgggagatcaagtcgctgtgaatcaaactttga gcattcacgaacctactgctgctcatgcagagatgccaaagcgcaagatagagtctcatgcttctgaagatgatttccgtcgt caaagttctaagaaaaagcttcaggctccgacgaatgctctgaagagcgtgaagaaggcacgacctgggaggaaccag aagagcattgtgtgtggtgatgaggaagagaacaatgccaggagcagtggccggagttgctgcagctacagctctgagg aagactcacaagctttccaggctgatcttaatgcaaaaacacgatcgaatcgatggccagccacagatcctcaaagcctct atgcaaagcaaagaagggaaagaatcaatgctagattgaggacattgcagaacctggtgcctaatggaactaaagttgac attagcacaatgctcgaagaagctgttcgttacgtcaagttcttgcagctgcagataaagcttttgagctcggatgagctgtg gatgtacgctcctgttgtccacagtgggatgattgatggccaagtcaactcagagatatttgtgtctgcaaatactcgtaatga gtggttctga Medicago truncatula MtRSLa amino acid sequence (SEQ ID NO: 88; AC140548.11 GI: 156231148) MEPIGTFPEGEWDFFRKMFASEDHEYYSQQFLDQNSLLLGENDGLNNGTQST FCTAEIGENERMFYSFDHAHIQNSNYIPQTQENSYNSNSSASDDTNYYFSYPN HVLENNINNCISNDFRMDENLFASSVPSLNEIVMEENVRMNEDSASDDHIVEK NGYNTQIMEPFDLHTKHEMQMKLKRKLDVIEVEVPVEEKINNNPKKKPRVS NDGQGCMKNARSKKNHKVIASHEEEMTEEINRGSNGNSSSSNISEDDNASQE NSGGTTLNSNGKTRASRGSATDPQSLYARKRRERINERLRVLQNLVPNGTKV DISTMLEEAVNYVKFLQTQIKLLSSDDMWMYAPLAYNGLDLGLNLNLNSSLP L* Medicago truncatula nucleotide sequence (SEQ ID NO: 89, AC140548.11 GI: 156231148) atggaacctataggtactttccctgaaggagaatgggatttctttcgcaaaatgtttgcaagtgaagatcatgaatattactcac aacaatttcttgatcaaaattcacttcttctaggggaaaatgatgggttgaacaatggaacacagtccacattttgcactgctga aattggtgaaaatgagcgtatgttttattcttttgatcatgctcatatccaaaactctaactatattcctcaaactcaagagaatag ttacaatagcaattctagtgctagtgatgatacaaattactattttagttatcctaatcatgtactagaaaataatattaataattgta tatccaatgattttcgcatggatgagaatttgtttgcttcttctgttccatcccttaatgagattgtaatggaagagaatgtgagaa tgaatgaagattctgcaagtgatgatcatattgtggagaaaaatggttacaatactcaaataatggaaccttttgatcttcacac caagcatgagatgcaaatgaagctcaaaaggaaacttgatgtgatagaagtggaggttcccgttgaagaaaaaattaacaa caatccgaagaaaaaacctcgtgtttcgaatgatggccaaggatgcatgaaaaatgcaaggtcaaagaagaaccacaaa gttattgctagccatgaagaggagatgacagaagagattaatagaggatcaaatggaaatagttctagtagtaacatttctga ggatgataatgcttctcaagaaaatagtggaggaactactctcaactcaaatgggaagacaagagctagtagaggatctgc aacagatccccaaagtctatatgcaaggaaaagaagagagagaataaatgaacgactaagagtcttacaaaatcttgtacc aaacggaacaaaggttgatatcagtacaatgcttgaagaggcagtcaattatgtgaaatttttacagactcaaatcaagctttt gagctctgatgatatgtggatgtatgcaccacttgcttacaatggacttgaccttggactcaatctcaacctcaacagctctcta ccactatga Soybean GmRSLa amino acid sequence (SEQ ID NO: 90) (gi|26056905|gb|CA799819.1|CA799819) XFLCFSQGSSSSTDNSGNNIFSITSSGAYSCDPEANFDSVSMVLCLGDAKFSPH SFQCDDNSNQQINENTDEESSLDPWKLAIADNNLQAKREYEMMVSEPVEVD RSRNLENLAKRLKSSIEVSKTLRSAKSGKNSKSASVSNDEDDRSLSLQAQRNS CFSQSDSNAYLEPNGGASKDPAPPNLHRKSRATTGAATDPQSLYARKRRERI NERLRILQNLVPNGTKVDISTMLEEAVQYVKFLQLQIKLLS SDDLWMY Soybean GmRSLa nucleotide sequence (SEQ ID NO: 91) (gi|26056905|gb|CA799819.1|CA799819) ATTTTTTGTGTTTCTCACAAGGGAGTAGCTCCAGTACTGATAATAGTGGTA ATAATATCTTTTCCATTACAAGTAGTGGAGCCTACTCCTGTGATCCAGAAG CAAACTTTGATTCTGTGTCCATGGTTTTGTGCCTTGGAGATGCCAAATTTA GTCCCCATAGTTTTCAATGTGATGACAACTCAAACCAACAGATAAATGAA AACACTGATGAAGAGTCAAGTCTAGACCCATGGAAGTTGGCTATAGCTGA CAATAATTTGCAGGCTAAGAGGGAGTATGAAATGATGGTTTCTGAACCTG TAGAAGTGGATAGAAGCAGAAACCTGGAGAACCTAGCAAAAAGACTAAA GAGTTCAATAGAGGTTTCAAAAACATTGAGGAGTGCTAAATCAGGGAAA AATTCAAAATCTGCTTCAGTGAGCAACGATGAAGATGATAGAAGCTTGAG CCTCCAAGCCCAAAGGAATAGCTGTTTTTCACAGAGTGACTCTAATGCTT ATCTGGAGCCAAATGGAGGGGCATCAAAAGATCCTGCACCTCCCAATTTG CATAGAAAATCAAGAGCAACTACCGGTGCTGCCACTGATCCACAGAGCCT CTATGCAAGAAAGAGAAGAGAAAGAATAAATGAAAGGTTGAGAATACTG CAAAATCTTGTTCCCAACGGAACTAAGGTGGATATCAGCACCATGCTTGA GGAAGCTGTCCAATACGTGAAGTTTTTACAGCTCCAAATTAAGCTTCTGA GCTCTGACGATCTGTGGATGTAT Soybean GmRSLb amino acid sequence (SEQ ID NO: 92) (gi|15663066|gb|B1700437.1|B1700437) XNLENLPKRLKSS1EVPKTSRNAKSRKNSKSASTSNDEDDRSLSLQVQRNNSC FSQSDSNAYLEPNGGASKDPAPPNLDRKSRATTSAAADPQSLYARKRRERIN ERLRILQNLVPNGTKVDISTMLEEAVQYVKFLQLQIKLLS SEDLWMYAPIVYN GINIGLDLGISPTKGRSM* Soybean GmRSLb nucleotide sequence (SEQ ID NO: 93). (gi|15663066|gb|B1700437.1|B1700437) GAAACCTGGAGAACCTACCAAAAAGACTAAAGAGCTCAATAGAGGTCCC AAAAACATCGAGGAATGCTAAATCAAGGAAAAATTCAAAATCTGCTTCA ACTAGCAACGATGAAGATGATAGAAGCTTGAGCCTCCAAGTCCAAAGGA ATAATAGCTGTTTTTCACAGAGTGACTCTAATGCTTATCTTGAGCCAAATG GAGGGGCATCAAAAGATCCTGCACCTCCTAATTTGGATAGAAAATCAAGA GCAACTACCAGTGCCGCCGCTGATCCACAGAGCCTCTATGCAAGAAAGAG AAGAGAAAGAATAAATGAAAGGCTGAGAATACTGCAAAATCTTGTCCCC AACGGAACTAAGGTGGATATCAGCACCATGCTTGAAGAAGCTGTCCAATA CGTTAAGTTTTTACAGCTCCAAATTAAGCTTCTGAGCTCTGAAGATTTGTG GATGTATGCTCCAATTGTTTACAATGGAATAAACATTGGACTAGACCTCG GTATTTCTCCAACCAAAGGAAGATCAATGTGATAGCATAGCAATTAAAGA GGATATAATATTTCATTAACTTA Lettuce saligna LsRSLa amino acid sequence (SEQ ID NO: 94) (gi|83790803|gb|DW051020.1|DW051020 CLLX3812.b1_H18.ab1) XRSKEAEILSSNGKRKASRGSATDPQSVYARKRRER1NERLRILQNLVPNGTK VDISTMLEEAVEYVKFLQLQIKLLSSDDMWMYAPIAYDGMDIGLHSTTIPSSS TR* Lettuce saligna LsRSLa nucleotide sequence (SEQ ID NO:95) (gi|83790803|gb|DW051020.1|DW051020 CLLX3812.bl_H18.abl) TGAGATCAAAAGAGGCTGAAATTCTGAGCTCAAATGGCAAGAGAAAAGC AAGTAGGGGGTCAGCAACTGATCCACAAAGTGTCTATGCACGGAAAAGA AGAGAAAGAATTAACGAACGTTTAAGAATATTACAAAATCTTGTTCCTAA TGGTACAAAGGTTGATATAAGCACAATGCTTGAAGAGGCTGTTGAGTACG TGAAGTTTTTGCAGCTTCAAATCAAGCTCTTGAGCTCCGATGATATGTGGA TGTATGCTCCGATTGCATACGATGGAATGGACATTGGGCTTCATTCAACA ACCATCCCATCATCGTCAACAAGATAATGCAAAGTTGGGCTATCCATATT GTCACATTTTTGTTGAATAAAAGGCAATCGATAACAAAATTCAAAGTTTA TAAAGAGTACACATTTATGC Triticum aestivum TaRSLa amino acid sequence (SEQ ID NO: 96) (gi|25232820|gb|CA654295.1|CA654295) MASKRATTRELRAMYDDEPSSMSLELFGYHGVVVDGDDENDDTATALPQLS FVDNFKGGCGSAADYYSWAYNASGGTPGASSSSTSSVLSFEHAGGAGHQLA YNSGTGDDDCALWMDSMADHQHGAARFGFMNPGSADVVPEIQESSIKQPA KSAQKRSSSGGEAQAAAKKQCGGGRKSKAKVVPTKDPQSAVAKVRRERISE RLKVLQDLVPNGTKVDMVTMLEKAITYVKFLQLQVKVLATDEFWPVQGGK APELSQVKTALDAILSSQQQP* Triticum aestivum TaRSLa nucleotide sequence (SEQ ID NO:97) (gi|25232820|gb|CA654295.1|CA654295) ATGGCGAGCAAGCGGGCCACCACGCGGGAGCTCCGGGCGATGTACGACG ACGAGCCCTCCTCCATGTCCCTCGAGCTCTTCGGCTACCATGGCGTGGTCG TCGACGGTGACGATGAAAACGACGACACTGCCACCGCCCTGCCCCAGCTC TCCTTCGTCGACAACTTCAAAGGTGGGTGCGGGTCGGCGGCGGACTACTA CAGCTGGGCGTACAACGCCTCCGGCGGGACGCCGGGCGCCTCCTCCAGCT CCACCTCGTCGGTGCTCAGCTTTGAGCATGCCGGCGGTGCCGGTCATCAG CTGGCTTATAATTCCGGCACAGGCGACGATGACTGCGCGCTCTGGATGGA CAGCATGGCCGATCATCAGCACGGCGCGGCCAGGTTTGGGTTCATGAACC CAGGGTCGGCCGATGTCGTCCCAGAAATCCAGGAGAGCAGCATCAAGCA GCCGGCCAAGTCTGCGCAGAAGCGCTCGAGCTCGGGTGGTGAGGCGCAA GCAGCGGCGAAGAAGCAGTGTGGAGGAGGCAGGAAGAGCAAGGCCAAA GTTGTCCCTACCAAGGATCCTCAGAGCGCTGTTGCAAAGGTCCGAAGAGA GCGCATCAGTGAGAGGCTCAAAGTTCTGCAGGATCTTGTACCCAACGGCA CGAAGGTGGACATGGTCACCATGCTCGAGAAGGCAATCACCTATGTCAAG TTCCTGCAGCTGCAAGTCAAGGTGTTGGCGACCGACGAGTTCTGGCCGGT GCAAGGAGGGAAGGCGCCGGAGCTCTCCCAAGTGAAGACCGCGCTGGAC GCCATCCTTTCTTCCCAGCAGCAACCCTAG Safflower Carthamus tinctorius CtRSLa amino acid sequence (SEQ ID NO: 98) (gi|125399878|gb|EL411863.1|EL411863 CFF59477.b1_118.ab1) DSQIIHPMPCDELHKSLI*LYHIRRRYPYWVFTDGESTSFARPLLNDSRIRGELL LTLSTTKHCKVTASSMRRSYSMMHDHEKS*KIQRRKSQKLVSKGNESEADH DAVFGQIMKMCGSDNDSNWPRESSTSPRPKEAANLNSNGKTKANRGSATDP QSVYARKRRERINERLRILQSLVPNGTKVDISTMLEDAVQYVKFLQLQIKPLS SDDLWMYAPIAYNGMETGLDSTIPSPR*RLSKVAASFFLKKGKPGA Safflower Carthamus tinctorius CtRSLa nucleotide sequence (SEQ ID NO: 99) (gi|125399878|gb|EL411863.1|EL411863 CFF59477.b1_118.ab1) GATTCACAGATAATCCACCCTATGCCGTGTGATGAACTCCACAAATCCTT AATTTAATTGTACCACATCAGGCGACGTTATCCATATTGGGTGTTCACTGA TGGTGAAAGCACATCTTTCGCGCGACCTCTACTCAATGACTCAAGAATTA GAGGTGAACTATTGCTTACACTATCTACTACTAAACATTGTAAAGTGACT GCCAGTTCTATGAGACGTTCGTATAGCATGATGCATGATCATGAGAAAAG CTAAAAGATACAGCGCAGAAAGAGCCAGAAGCTCGTTTCTAAAGGCAAC GAAAGTGAAGCTGACCATGATGCAGTTTTTGGGCAAATAATGAAAATGTG TGGATCTGACAATGACTCGAATTGGCCTCGGGAGTCGAGCACAAGTCCAA GACCAAAAGAGGCTGCAAATCTGAACTCAAATGGGAAGACAAAAGCAAA TAGGGGGTCAGCAACGGATCCACAAAGTGTCTACGCACGGAAGAGAAGA GAACGAATTAATGAACGGTTAAGAATACTACAGAGTCTGGTTCCTAATGG TACAAAGGTTGATATAAGCACAATGCTTGAAGATGCTGTCCAGTATGTGA AATTTTTGCAGCTCCAAATCAAGCCGTTGAGCTCTGATGATCTGTGGATGT ATGCCCCCATCGCGTACAACGGGATGGAGACGGGGCTTGATTCTACGATC CCCTCGCCAAGGTGAAGACTATCCAAAGTTGCCGCATCTTTTTTCTTGAAA AAAGGGAAGCCTGGGGCAA BdRSLa amino acid sequence (SEQ ID NO: 100) MALVREPMVLYDGGFDASEASAFDSIGCFGHGHGHDALLGGVDAAALFGG YAHDEPAGASASAYVKDGSHWAGVGASVLAFDRAARGHGAQAMATAAAQ EEEECDAWIDAMDEDNGEAAPAPSIGFDPATGCFSLTQRPGAGARRPFGLLFP SASGGAPSPDSAAPAPASRGSQKRPSAGIARAQDAEPRASKKQCGASRKTTA KAKSPAPAITSPKDPQSLAAKNRREKISERLRTLQEMVPNGTKVDMVTMLEK AISYVKFLQLQVKVLATDEFWPAQGGMAPEISQVKEALDAILSSQRGQFNCS S* BdRSLa nucleotide sequence (SEQ ID NO: 101) ATGGCATTAGTGCGGGAGCCGATGGTACTGTATGACGGCGGTTTCGACGC CTCGGAGGCGTCGGCATTCGACTCCATCGGCTGCTTCGGCCACGGCCACG GCCACGACGCGCTCCTAGGCGGCGTCGACGCGGCCGCGCTGTTCGGGGGC TACGCGCACGACGAGCCGGCCGGCGCCAGCGCCAGCGCCTACGTGAAGG ACGGCTCGCACTGGGCCGGCGTGGGTGCGTCCGTGCTCGCGTTCGACCGT GCCGCTCGGGGCCACGGCGCGCAGGCCATGGCGACCGCGGCCGCTCAGG AGGAGGAAGAATGCGACGCGTGGATCGACGCCATGGACGAGGACAATGG CGAGGCGGCGCCGGCGCCGTCCATCGGCTTCGACCCGGCCACGGGCTGCT TCAGCCTCACGCAGCGGCCCGGCGCCGGCGCGCGGCGCCCGTTCGGGCTC CTGTTCCCGAGCGCGTCCGGTGGCGCGCCCTCGCCCGACAGCGCCGCGCC AGCGCCGGCATCCCGCGGTTCCCAGAAGCGGCCATCCGCCGGGATTGCGC GCGCGCAGGACGCGGAGCCGCGGGCCAGCAAGAAGCAGTGCGGCGCGAG CAGGAAGACGACGGCCAAGGCGAAGTCGCCTGCGCCTGCCATCACCTCG CCCAAGGACCCGCAGAGCCTCGCTGCAAAGAACCGGAGGGAGAAGATCA GCGAGCGGCTCCGGACGTTGCAGGAGATGGTGCCCAACGGCACCAAGGT GGACATGGTCACCATGCTCGAGAAGGCCATCAGCTACGTCAAGTTCCTGC AGCTGCAAGTCAAGGTGCTCGCGACGGACGAGTTCTGGCCGGCGCAGGG AGGGATGGCGCCGGAGATCTCCCAGGTGAAGGAGGCGCTCGACGCCATC CTGTCGTCGCAGAGGGGGCAATTCAACTGCTCCAGCTAG BdRSLb amino acid sequence (SEQ ID NO: 102) MASRHATTREPHLRTMYDDEPSMSLELFGYHGVVVDGDDDGDTATDLPQLT FVDNFKGGCGSADYYGWAYSASGGASGACSSSSSSVLSFEQAGGAGHQLAY NAGTGDDDCALWMDGMADQHDTAKFGFMDPGMSDVSLEIQESSMKPPAK MAQKRACQGGETQAAAKKQCGGSKKSKAKAAPAKDPQSAVAKVRRERISE RLKVLQDLVPNGTKVDMVTMLEKAITYVKFLQLQVKVLATDDFWPVQGGK APELSQVKDALDAILSSQNQS* BdRSLb nucleotide sequence (SEQ ID NO: 103) ATGGCAAGCAGGCACGCCACTACACGGGAGCCACACCTCCGGACCATGT ACGACGACGAGCCATCCATGTCCCTCGAGCTCTTCGGCTACCATGGCGTC GTCGTCGACGGTGACGACGATGGCGACACCGCCACCGACCTTCCCCAGCT CACCTTTGTTGACAACTTCAAAGGCGGGTGTGGGTCAGCCGACTACTACG GCTGGGCGTACAGCGCCTCCGGTGGTGCGTCAGGCGCCTGCTCCAGCTCC AGCTCGTCGGTGCTCAGCTTTGAGCAGGCGGGTGGTGCCGGTCATCAGCT GGCTTATAACGCCGGCACAGGTGACGATGACTGCGCGCTCTGGATGGACG GCATGGCTGACCAGCATGACACAGCCAAGTTTGGGTTCATGGACCCAGGC ATGTCTGATGTCAGCCTAGAAATCCAGGAGAGCAGCATGAAACCGCCGG CCAAGATGGCACAGAAGCGCGCTTGCCAGGGTGGTGAGACGCAAGCAGC GGCGAAGAAGCAGTGTGGAGGAAGCAAGAAGAGCAAGGCAAAAGCTGC CCCTGCCAAGGATCCTCAAAGCGCCGTTGCAAAGGTCCGAAGAGAGCGC ATCAGCGAGAGGCTCAAAGTTCTGCAGGATCTCGTGCCCAATGGCACAAA GGTTGACATGGTCACCATGCTCGAAAAGGCAATCACCTATGTCAAGTTCC TGCAGCTGCAAGTCAAGGTATTGGCGACTGATGACTTCTGGCCGGTGCAA GGAGGGAAAGCTCCGGAGCTCTCCCAAGTGAAGGACGCTCTGGACGCGA TCCTGTCTTCCCAGAATCAATCCTAG BdRS Lc amino acid sequence (SEQ ID NO: 104) MALVGQATKLCYDGFAGDGVPPFMDAACLAFDHGYDYNNPHAWEFPTGAE PGNSSAFDVAWTGVSSTSPVLTFDAAEWMDATATDRLSSYSPSAATVPASYK RPRAHVQPQQEAEEQESITPNPKKQCGDGKVVIKSSAAATGTSPRKEPQSQA AKSRRERIGERLRALQELVPNGSKVDMVTMLDKAITYVKFMQLQLTVLETD AFWPAQGGAAPEISQVKAALDAIILSSSQKPRQWS* BdRS Lc nucleotide sequence (SEQ ID NO: 105) ATGGCTCTAGTGGGTCAGGCAACGAAGCTCTGCTACGACGGCTTCGCCGG AGACGGTGTGCCGCCGTTCATGGACGCAGCTTGTCTGGCATTCGACCACG GGTATGATTACAACAATCCCCACGCATGGGAATTCCCCACCGGCGCCGAG CCAGGCAACAGCAGCGCGTTCGACGTTGCCTGGACCGGCGTCTCCTCCAC TTCTCCGGTGCTCACATTCGACGCCGCCGAGTGGATGGACGCCACGGCCA CGGACCGGCTGAGCTCCTACAGCCCGTCTGCGGCCACCGTGCCGGCCTCT TACAAGCGGCCTCGTGCGCACGTGCAGCCACAGCAGGAAGCAGAAGAAC AGGAAAGCATTACTCCCAATCCCAAGAAGCAGTGCGGCGATGGGAAAGT AGTTATCAAGTCATCGGCGGCGGCTACCGGCACCAGTCCACGCAAGGAAC CCCAAAGCCAAGCTGCCAAGAGCCGTCGTGAGCGGATCGGCGAGCGGCT GAGAGCGCTGCAGGAGCTGGTGCCCAACGGCAGCAAGGTGGACATGGTC ACCATGCTCGACAAGGCCATCACTTATGTCAAGTTCATGCAGCTCCAGCT CACGGTGCTCGAGACAGACGCGTTCTGGCCTGCGCAGGGTGGCGCGGCGC CGGAGATCTCCCAGGTGAAGGCGGCGCTCGACGCCATCATCCTCTCCTCG TCGCAGAAGCCTCGTCAGTGGAGCTAG BdRSLd amino acid sequence (SEQ ID NO: 106) MEAGGLISEAGWTMFDFPSQGEESEIMSQLLGAFPSHLEEGHQDLPWYQASD PSYYDCNLNTSSESNASSLAVPSECMGYYLGDSSESLDLSSCIAPNDLNLVQE QDATEFLNMTPNLSLDLRGNGESSCEDLTSVGPTNKRKHSSAEEGIDCQARG QKFARKAEPKRTKKTKQSGWEVAVATRNGSTASCCTSDDDSNASQESADTG VCPKGKARAARGASTDPQSLYARKRRERINERLKTLQTLVPNGTKVDMSTM LEEAVHYVKFLQLQIKVLSSDDMWMYAPLAYNGMNIGLDLNIYTPERWRTA SAAPSTEGREYAGVDRISDLPDGILGDIVSLLPTAEGARTQILKRRWRHIWRC SAPLNLDCCTLVARGGGREAEDELVGLIPSILSSHQGTGRRFHVPSSRHSDRA ATIEAWLQSAALDNLQELDLWCTHTYLYDYVPLPPAVFRFSATVRVVTIANC NLRDSAVQGLQFPQLKQLGFKDIIIMEDSLHHMIAACPDLECLMIERSLGFAC VRINSLSLRSIGVSTDHPHPHELQFVELVIDNAPCLKRLLHLEMCYHLDMHIT VISAPKLETLSCCSSVSRSSTKLSFGSAAIQGLHIDSLTTVVRTVQILAVEMHSL CLDTIIDFMKCFPCLQKLYIKSFVSGNNWWQRKHRNVIKSLDIRLKTIALESY GGNQSDINFVTFFVLNARVLELMTFDVCSEHYTVEFLAEQYRKLQLDKRASR AARFHFTSNRCVRGIPYIGRAELFLPIKCSHVDTSPNLSSFRLSAVFSVCITRNL LRLKKAMWVISLYYSPEFTKQVAVHNPNEMPF* BdRSLd nucleotide sequence (SEQ ID NO: 107) ATGGAGGCTGGAGGGCTGATTTCTGAGGCTGGCTGGACCATGTTTGACTT CCCGTCGCAAGGCGAGGAATCAGAGATCATGTCGCAGCTGCTAGGCGCCT TCCCCTCCCATCTTGAGGAAGGCCATCAGGATCTGCCTTGGTACCAGGCTT CTGACCCATCCTACTATGACTGTAATCTTAATACAAGTAGTGAAAGCAAT GCTAGTAGTCTTGCTGTTCCATCCGAGTGTATGGGCTACTATTTGGGTGAT TCAAGTGAGTCCCTGGACCTGAGCTCCTGCATTGCACCAAATGACCTGAA CTTGGTCCAGGAGCAAGATGCAACTGAGTTTCTGAATATGACACCAAATC TTTCCCTTGATTTACGTGGGAATGGTGAGTCGAGCTGCGAGGATCTCACTT CGGTCGGTCCTACTAACAAGCGAAAGCACTCCTCGGCAGAAGAAGGAAT CGACTGCCAAGCAAGAGGCCAGAAATTCGCCAGAAAGGCTGAACCGAAG CGAACAAAGAAGACCAAGCAAAGCGGATGGGAGGTTGCTGTTGCCACCA GGAATGGAAGCACAGCGAGCTGCTGCACCTCTGATGATGACTCAAACGCT TCTCAAGAATCTGCAGATACCGGTGTTTGTCCGAAAGGCAAGGCTCGGGC TGCCCGTGGCGCATCAACTGATCCCCAGAGCCTCTATGCAAGGAAAAGGA GGGAAAGGATCAATGAGAGACTGAAGACACTGCAGACCCTTGTGCCCAA TGGAACCAAAGTAGATATGAGCACCATGCTTGAGGAGGCAGTCCACTACG TGAAGTTCCTGCAGCTTCAGATCAAGGTCTTGAGCTCTGATGATATGTGG ATGTATGCGCCGCTAGCATACAACGGGATGAACATTGGGCTTGATCTGAA CATATATACTCCGGAGAGGTGGAGGACAGCGTCCGCGGCGCCCTCAACCG AAGGGCGTGAATACGCCGGCGTCGACCGCATCAGCGACCTCCCCGACGG CATCCTCGGCGACATCGTCTCGTTGCTCCCCACCGCCGAAGGAGCCCGCA CCCAGATCCTCAAGCGCAGGTGGCGCCACATCTGGCGCTGCTCCGCCCCT CTCAACCTCGATTGCTGTACCTTGGTCGCCCGTGGCGGCGGCCGTGAGGC TGAAGATGAACTCGTCGGTCTCATACCGTCCATCCTTTCTTCTCACCAAGG CACCGGCCGCCGCTTCCACGTCCCCTCGTCGCGCCACTCTGACCGAGCTG CTACCATTGAAGCCTGGCTCCAATCTGCTGCCCTCGACAATCTCCAGGAG CTCGATTTATGGTGCACCCACACCTATCTTTACGACTATGTTCCGCTGCCA CCCGCCGTCTTTCGCTTCTCCGCCACCGTCCGTGTTGTCACCATCGCAAAT TGTAACCTCCGTGACAGCGCCGTCCAAGGCCTTCAATTCCCACAACTTAA ACAGCTCGGATTCAAAGATATCATCATCATGGAGGATTCGCTGCACCACA TGATTGCTGCGTGTCCAGATCTCGAGTGCTTGATGATTGAAAGGAGCTTA GGTTTTGCTTGCGTCCGGATCAATTCCCTTAGTCTTAGAAGCATCGGTGTG AGCACTGACCACCCTCACCCACATGAGCTCCAGTTTGTGGAACTCGTCAT TGATAATGCACCTTGTCTTAAGAGATTGCTCCATCTTGAAATGTGTTATCA CCTTGACATGCATATAACAGTAATCTCCGCGCCTAAACTGGAGACCTTGA GCTGCTGTTCTTCTGTGAGTCGCTCCTCCACCAAACTCTCGTTTGGCTCCG CGGCCATTCAGGGATTGCACATTGATAGCCTAACAACAGTGGTGCGCACT GTCCAAATTTTAGCTGTAGAGATGCATTCTCTTTGTCTAGACACAATTATT GACTTCATGAAATGCTTTCCATGTCTGCAGAAGTTGTACATTAAGTCATTT GTAAGTGGAAACAATTGGTGGCAACGTAAACACCGGAACGTTATCAAATC CCTTGACATCCGTCTCAAGACAATAGCGTTGGAAAGTTATGGGGGCAATC AGTCTGACATCAACTTTGTCACATTCTTTGTCTTGAACGCGAGAGTGCTAG AGTTGATGACATTTGACGTTTGTTCTGAGCATTACACTGTGGAGTTCTTGG CAGAGCAATATAGGAAGCTTCAGCTAGATAAGAGGGCTTCAAGAGCCGC TCGGTTCCATTTTACAAGTAACCGATGTGTCCGTGGTATTCCGTATATCGG ACGTGCCGAGCTATTCTTGCCTATCAAATGTTCTCATGTTGACACCAGTCC AAACTTGAGTAGTTTCCGTTTGTCTGCAGTATTTTCAGTTTGTATTACCCG GAACCTTTTGCGTTTAAAAAAAGCTATGTGGGTCATTAGTTTGTATTATTC TCCAGAATTTACAAAACAAGTGGCCGTGCACAATCCCAATGAAATGCCGT TTTAG BdRS Le amino acid sequence (SEQ ID NO: 108) MEAKCGAIWSSIDARSEDSEMIAHLQSMFWSNSDVALNLCSSNTSGNSCVTA STLPSSLFLPLVDNESYGAAPSVDTGMDSCFDHQHQSITGHKRISHMDEQMK KTRKKSRTVPSVSKALGSSLVDNQMNADIFNQSSSCCSSGEDSIGTSEKSIVA NQSDNTSGCKRPSKNMQSLYAKKRRERINEKLRVLQQLIPNGTKVDISTMLE EAVQYVKFLQLQIKVLSSDETWMYAPLAYNGMDIGLTLALRTAANQE* BdRS Le nucleotide sequence (SEQ ID NO: 109) ATGGAGGCCAAGTGTGGAGCTATTTGGAGCTCTATCGATGCGAGGAGCGA GGACTCTGAGATGATTGCTCACCTGCAGTCCATGTTCTGGAGCAACAGTG ATGTTGCTCTCAACCTCTGTTCGTCAAACACCAGTGGCAATTCTTGTGTCA CAGCTAGCACATTGCCTAGCAGCTTGTTCCTTCCTCTTGTCGATAATGAGA GCTATGGTGCAGCGCCATCGGTGGACACCGGCATGGATTCATGCTTTGAT CACCAGCATCAGAGCATTACTGGTCACAAGAGGATATCGCACATGGATGA GCAGATGAAGAAGACGAGAAAGAAGTCCCGGACTGTTCCATCGGTATCA AAGGCTCTGGGTTCCAGCCTAGTCGATAATCAGATGAATGCTGACATTTT CAATCAGAGCTCCTCCTGCTGCAGCTCGGGAGAAGATTCAATTGGAACAT CTGAGAAATCCATTGTTGCAAACCAGAGTGACAATACGAGTGGTTGTAAG CGGCCTTCAAAGAATATGCAAAGCCTTTATGCAAAGAAGAGAAGAGAGA GGATCAACGAGAAGTTGAGAGTACTGCAGCAGCTGATTCCCAATGGCACC AAAGTTGACATCAGCACAATGTTGGAGGAAGCAGTTCAGTATGTCAAGTT TCTGCAGCTGCAAATAAAGGTCTTAAGCTCTGACGAGACATGGATGTATG CGCCCCTCGCCTACAATGGTATGGACATCGGTCTCACTCTCGCTCTGAGA ACTGCTGCAAACCAAGAGTGA Zea mays ZmRSLa amino acid sequence (AZM4_60871: SEQ ID NO: 110) MALVREHGGYYGGFDSVEAAAFDTLGYGHGASLGFDASSALFGEGGYAAG GGDAWAGAGASTVLAFNRTTAAAAVGVEEEEEECDAWIDAMDEDDQSSGP AAAAPEARHALTASVGFDASTGCFTLTERASSSSGGAGRPFGLLFPSTSSSGG TPERTAPVRVPQKRTYQAVSPNKKHCGAGRKASKAKLASTAPTKDPQSLAA KQNRRERISERLRALQELVPNGTKVDLVTMLEKAISYVKFLQLQVKVLATDE FWPAQGGKAPEISQVREALDAILSSAS Zea mays ZmRSLa nucleotide sequence (AZM4_60871: SEQ ID NO: 111) ATGGCGTTGGTGAGGGAGCACGGTGGGTACTACGGAGGCTTCGACAGCGT CGAGGCGGCGGCCTTCGACACGCTCGGCTACGGCCACGGCGCGTCGCTGG GCTTTGACGCGTCGTCGGCGCTGTTCGGGGAAGGCGGTTATGCGGCGGGC GGCGGGGACGCCTGGGCGGGCGCGGGGGCGTCGACCGTCCTGGCGTTCA ACCGCACAACGGCAGCGGCGGCCGTGGGTGTGGAAGAGGAGGAGGAGG AGTGCGACGCGTGGATCGACGCTATGGACGAGGACGACCAGAGCTCCGG CCCCGCCGCGGCGGCGCCAGAGGCGCGCCACGCGCTGACGGCCTCCGTG GGTTTCGACGCCTCCACGGGGTGCTTCACCCTGACGGAGAGGGCGTCGTC GTCGTCAGGCGGAGCGGGGCGCCCGTTCGGCCTGCTGTTCCCGAGCACGT CGTCGTCGGGCGGCACGCCCGAGCGCACGGCGCCGGTGCGCGTCCCGCA GAAACGGACCTACCAGGCTGTGAGCCCCAACAAGAAGCACTGCGGCGCG GGCAGGAAGGCGAGCAAGGCCAAGCTCGCGTCCACAGCCCCAACCAAAG ATCCCCAGAGCCTCGCGGCCAAGCAGAACCGGCGCGAGCGGATCAGCGA GCGGCTGCGGGCGCTGCAGGAGCTGGTGCCCAACGGCACCAAGGTCGAC CTGGTCACCATGCTCGAGAAGGCCATCAGCTACGTTAAGTTCCTCCAGTT GCAAGTCAAGGTTCTGGCAACAGACGAATTCTGGCCGGCACAGGGAGGG AAGGCGCCGGAGATCTCCCAGGTGAGGGAGGCGCTCGACGCCATCTTGTC GTCGGCGTCG Zea mays ZmRSLb amino acid sequence (AZM4_70092: SEQ ID NO: 112) MAQFLGAADDHCFTYEYEHVDESMEAIAALFLPTLDTDSANFSSSCFNYAVP PQCWPQPDHSSSVTSLLDPAENFEFPVRDPLPPSGFDPHCAVAYLTEDSSPLH GKRSSVIEEEAANAAPAAKKRKAGAAMQGSKKSRKASKKDNIGDADDDGG YACVDTQSSSSCTSEDGNFEGNTNSSSKKTCARASRGAATEPQSLYARKRRE RINERLRILQNLVPNGTKVDISTMLEEAAQYVKFLQLQIKLLSCDDTWMYAPI AYNGINIGNVDLNIYSLQK* Zea mays ZmRSLb nucleotide sequence (AZM4_70092: SEQ ID NO: 113) ATGGCTCAGTTTCTTGGGGCGGCTGATGATCACTGCTTCACCTACGAGTAT GAGCATGTGGATGAGTCCATGGAAGCAATAGCAGCCCTGTTCTTGCCTAC CCTTGACACCGACTCCGCCAACTTCTCCTCTAGCTGTTTCAACTATGCTGT CCCTCCACAGTGCTGGCCTCAGCCAGACCATAGCTCTAGCGTTACCAGTTT GCTTGATCCAGCCGAGAACTTTGAGTTTCCAGTCAGGGACCCGCTCCCCC CAAGCGGCTTCGATCCACATTGCGCTGTCGCCTACCTCACTGAGGATTCG AGCCCTCTGCATGGCAAACGTTCATCAGTCATTGAGGAAGAAGCAGCCAA CGCCGCACCTGCTGCTAAGAAGAGGAAGGCTGGTGCTGCAATGCAGGGA TCAAAGAAATCCAGGAAGGCGAGCAAAAAGGATAACATCGGCGACGCCG ACGATGATGGCGGCTATGCCTGTGTTGACACGCAAAGCTCCAGTAGCTGC ACCTCCGAGGACGGGAACTTCGAAGGAAATACGAATTCAAGCTCCAAGA AGACCTGCGCCAGGGCCAGCCGCGGAGCAGCAACTGAACCTCAGAGTCT CTATGCAAGGAAGAGGAGAGAGAGGATCAACGAAAGGTTGAGAATCTTG CAGAACTTGGTTCCAAATGGAACAAAAGTAGACATTAGCACGATGCTCGA GGAAGCGGCGCAGTATGTCAAGTTTTTACAGCTCCAGATTAAGCTGTTGA GCTGTGACGACACATGGATGTATGCGCCAATCGCGTACAATGGAATTAAC ATCGGCAATGTTGATCTGAACATCTACTCTCTGCAAAAGTAA Zea mays ZmRSLc amino acid sequence (AZM4_91750: SEQ ID NO: 114) MEDGGLXSEAGAWAELGTGGDESEELVAQLLGAFFRSHGEEGRHQLLWSD DQASSDDVHGDGSLAVPLAYDGCCGYLSYSGSNSDELPLGSSSRAAPAGGPP EELLGAAETEYLNNVAAADHPFFKWCGNGEGLDGPTSVVGTLGLGSGRKRA RKKSGDEDEDPSTAIASGSGPTSCCTTSDSDSNASPLESADAGARRPKGNENA RAAGRGAAAATTTTAEPQSIYARVRRERINERLKVLQSLVPNGTKVDMSTML EEAVHYVKFLQLQIRVLQLLSSDDTWMYAPIAYNGMGIGIDLRMHGQDR* Zea mays ZmRSLc nucleotide sequence (AZM4_91750: SEQ ID NO: 115) ATGGAGGACGGAGGGTTGRTCAGCGAGGCCGGCGCCTGGGCCGAGCTCG GCACCGGCGGCGACGAGTCGGAGGAGCTGGTGGCGCAGCTGCTGGGCGC CTTCTTCCGGTCCCACGGCGAGGAAGGCCGGCACCAGCTGCTTTGGTCTG ACGACCAAGCTTCTTCCGACGACGTGCACGGCGACGGCAGCCTTGCCGTG CCGCTCGCATACGACGGCTGCTGCGGCTATCTGAGCTACTCAGGTAGCAA CTCGGACGAGCTCCCCCTCGGGAGCAGCTCCCGCGCTGCGCCAGCAGGTG GCCCACCGGAGGAGCTGCTCGGTGCAGCTGAGACTGAGTACCTGAATAAT GTGGCCGCCGCAGACCATCCCTTCTTCAAATGGTGTGGGAATGGTGAGGG TCTGGATGGTCCGACGAGCGTCGTGGGCACGCTTGGGCTTGGCTCGGGCC GGAAACGCGCGCGCAAGAAGAGCGGGGACGAAGACGAAGACCCGAGCA CGGCCATCGCCAGCGGAAGCGGCCCCACGAGCTGCTGCACTACCTCCGAC AGCGACTCAAACGCGTCTCCTCTGGAGTCCGCGGACGCCGGCGCTCGTCG CCCCAAGGGCAACGAGAATGCCCGGGCAGCTGGCCGCGGCGCGGCGGCG GCGACGACGACGACAGCGGAGCCCCAGAGCATCTACGCAAGGGTACGGA GGGAGCGGATCAACGAGAGGCTCAAGGTGCTGCAGAGCCTGGTGCCCAA CGGCACCAAGGTGGACATGAGCACCATGCTCGAGGAGGCCGTCCACTAC GTCAAGTTCCTGCAGCTTCAGATCAGGGTGCTGCAGCTCCTGAGCTCCGA CGACACGTGGATGTACGCGCCCATCGCGTACAACGGGATGGGCATCGGG ATCGACCTCCGCATGCATGGACAGGACAGATGA Zea mays amino acid sequence (AZM4_86104: SEQ ID NO: 116) SKKSRKASKKDCIVDDDDVYVDPQSSGSCTSEEGNFEGNTYSSAKKTCTRAS RGGATDPQSLYARKRRERINERLRILQNLVPNGTKVDISTMLEEAAQYVKFL QLQIKLLSSDDMWMYAPIAYNGINISNVDLNIPALQK* Zea mays ZmRSLd nucleotide sequence (AZM4_86104: SEQ ID NO: 117) TCAAAGAAATCCAGGAAGGCGAGCAAAAAAGATTGTATTGTCGATGACG ACGATGTCTATGTTGACCCGCAAAGCTCCGGTAGCTGCACCTCCGAGGAG GGGAATTTTGAAGGGAATACGTATTCAAGCGCGAAAAAGACCTGCACCA GGGCCAGCCGCGGAGGAGCAACTGATCCTCAGAGTCTCTATGCAAGGAA GAGGAGAGAGAGGATCAATGAAAGGTTGAGAATCTTGCAGAACTTGGTC CCCAATGGAACAAAGGTTGACATTAGTACGATGCTCGAGGAAGCAGCAC AGTATGTCAAATTTTTACAGCTTCAGATTAAGCTGTTGAGCTCTGACGACA TGTGGATGTATGCGCCAATCGCGTACAATGGGATCAACATCAGCAATGTT GATCTGAACATCCCTGCA

The invention is further described by the following numbered paragraphs:

1. An expression construct for constitutive expression of a plant transcription factor gene comprising an isolated plant nucleic acid sequence encoding a transcription factor operably linked to an isolated plant promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene.

2. An expression construct according to paragraph 1 wherein said promoter is a cell, tissue or organ specific promoter.

3. An expression construct according to paragraph 2 wherein said promoter is a root specific promoter.

4. An expression construct according to paragraph 3 wherein said promoter is EXP7.

5. An expression construct according to a preceding paragraph wherein said transcription factor is RSL4 or a functional homolog or ortholog thereof.

6. An expression construct according to any of paragraphs 1 to 4 wherein said transcription factor is selected from transcription factors listed in table 1.

7. An expression construct according to a preceding paragraph wherein said plant is a crop plant.

8. A vector comprising an expression construct according to any of paragraphs 1 to 7.

9. A vector according to paragraph 8 further comprising a second expression construct comprising an isolated plant nucleic acid sequence encoding said transcription factor operably linked to a second isolated plant promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed.

10. A vector according to paragraph 9 wherein the first promoter is EXP7.

11. A vector according to paragraph 8 or 9 wherein said transcription factor is RSL4 or a functional variant thereof.

12. A vector according to any of paragraphs 8 to 10 wherein said second promoter is GL2.

13. A host cell comprising an expression construct according to any of paragraphs 1 to 6 or a vector according to any of paragraphs 8 to 12.

14. A host cell according to paragraph 13 wherein said host cell is a plant cell.

15. A plant expressing a expression construct according to any of paragraphs 1 to 7 or a vector according to any of paragraphs 8 to 12.

16. A method for constitutive expression of a plant transcription factor gene comprising introducing the expression construct according to any of paragraphs 1 to 7 or vector according to any of paragraphs 8 to 12 into a plant host cell or plant expressing the transcription factor gene.

17. A method according to paragraph 16 comprising introducing the expression construct according to any of paragraphs 1 to 7 or vector according to any of paragraph 8 into a plant host cell or plant wherein said transcription factor gene is constitutively expressed in a cell or tissue in which it is normally expressed.

18. A method according to any of paragraph 16 comprising introducing a vector according to paragraph 9 to 12 into a host cell or organism wherein said transcription factor gene is constitutively expressed in a cell or tissue in which it is not normally expressed.

19. A method according to any of paragraphs 16 to 18 comprising introducing the expression construct according to any of paragraphs 1 to 7 and a second expression construct into said host cell or organism wherein said second expression construct comprises an isolated nucleic acid sequence encoding said transcription factor operably linked to a second isolated promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed.

20. A method for expression of a plant transcription factor in a tissue in which it is not normally expressed said method comprising introducing the vector of any of paragraphs 9 to 12 into a plant host cell or plant.

21. A composition comprising an expression construct for constitutive expression of a plant transcription factor gene comprising an isolated plant nucleic acid sequence encoding a transcription factor operably linked to an isolated plant promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene.

22. A composition according to paragraph 21 further comprising a second expression construct comprising an isolated plant nucleic acid sequence encoding said transcription factor operably linked to a second isolated plant promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed.

Having thus described in detail preferred embodiments of the present invention, it is to be understood that the invention defined by the above paragraphs is not to be limited to particular details set forth in the above description as many apparent variations thereof are possible without departing from the spirit or scope of the present invention. 

What is claimed is:
 1. An expression construct for constitutive expression of a plant transcription factor gene comprising an isolated plant nucleic acid sequence encoding a transcription factor operably linked to an isolated plant promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene.
 2. An expression construct according to claim 1 wherein said promoter is a cell, tissue or organ specific promoter.
 3. An expression construct according to claim 2 wherein said promoter is a root specific promoter.
 4. An expression construct according to claim 3 wherein said promoter is EXP7.
 5. An expression construct according to a preceding claim wherein said transcription factor is RSL4 or a functional homolog or ortholog thereof.
 6. An expression construct according to claim 1 wherein said transcription factor is selected from transcription factors listed in table
 1. 7. An expression construct according to claim 1 wherein said plant is a crop plant.
 8. A vector comprising an expression construct according to claim
 1. 9. A vector according to claim 8 further comprising a second expression construct comprising an isolated plant nucleic acid sequence encoding said transcription factor operably linked to a second isolated plant promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed.
 10. A vector according to claim 9 wherein the first promoter is EXP7.
 11. A vector according to claim 8 wherein said transcription factor is RSL4 or a functional variant thereof.
 12. A vector according to claim 8 wherein said second promoter is GL2.
 13. A host cell comprising an expression construct according to any of claims 1 to 6 or a vector according to claim
 8. 14. A host cell according to claim 13 wherein said host cell is a plant cell.
 15. A plant expressing a expression construct according to claim
 1. 16. A method for constitutive expression of a plant transcription factor gene comprising introducing the expression construct according to claim 1 into a plant host cell or plant expressing the transcription factor gene.
 17. A method according to claim 16 comprising introducing the expression construct into a plant host cell or plant wherein said transcription factor gene is constitutively expressed in a cell or tissue in which it is normally expressed.
 18. A method according to claim 16 comprising introducing the expression construct and a second expression construct into said host cell or organism wherein said second expression construct comprises an isolated nucleic acid sequence encoding said transcription factor operably linked to a second isolated promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed.
 19. A method for expression of a plant transcription factor in a tissue in which it is not normally expressed said method comprising introducing the vector of claim 9 into a plant host cell or plant.
 20. A composition comprising an expression construct for constitutive expression of a plant transcription factor gene comprising an isolated plant nucleic acid sequence encoding a transcription factor operably linked to an isolated plant promoter nucleic acid sequence wherein said promoter sequence is derived from the promoter sequence of a target gene of said transcription factor and wherein said transcription factor regulates expression of said target gene.
 21. A composition according to claim 20 further comprising a second expression construct comprising an isolated plant nucleic acid sequence encoding said transcription factor operably linked to a second isolated plant promoter nucleic acid sequence specific to a cell, tissue or organ in which said transcription factor is not normally expressed. 